Dopamine transporter-dependent induction of C-Fos in HEK cells

The psychostimulants cocaine and amphetamine increase expression of the immediate early gene (IEG) c-fos indirectly, via D1 dopamine receptor activation. To determine whether dopamine transporter substrates and inhibitors can affect c-Fos expression directly, we investigated their effects on c-Fos protein and c-fos mRNA in HEK-293 (HEK) cells transfected with the human dopamine transporter (hDAT). In untransfected HEK cells, methylphenidate and cocaine produced a small but statistically significant increase in c-Fos, whereas dopamine and amphetamine did not. In hDAT cells, DAT substrates (dopamine, amphetamine) increased c-Fos immunoreactivity 6- and 3-fold (respectively). The DAT inhibitors cocaine, methylphenidate, and bupropion also increased c-Fos approximately 3-fold in hDAT cells. If coincubated with dopamine, the inhibitors attenuated dopamine-induced c-Fos in hDAT cells. The magnitude of c-fos mRNA induction by substrates and inhibitors paralleled induction of c-Fos protein immunoreactivity. The results indicate that substrates or inhibitors of the DAT can trigger induction of IEG expression in the absence of D1 dopamine receptor. For substrates, IEG induction is DAT-dependent, but for certain DAT inhibitors the cellular response can be elicited in the absence of the DAT in HEK cells. Oxidative stress may partly, but not fully, account for the DA-induced c-Fos induction as an inhibitor of oxidative stress Trolox C, attenuated DA-induced c-Fos induction. Protein kinase C (PKC) may also partially account for c-Fos induction as a specific inhibitor of PKC Bisindolylmaleimide I (BIS) attenuated DA-induced c-Fos by 50%. DAT substrate and inhibitor effects on IEGs, other fos-related antigens, and possible mechanisms that contribute to c-Fos induction warrant investigation in presynaptic neurons as a potential contribution to the long-term effects of psychostimulants.     

Repeated cocaine administration differentially affects NMDA receptor subunit (NR1, NR2A-C) mRNAs in rat brain

We investigated the effects of intermittent intraperitoneal (i.p.) injections of cocaine (20 mg/kg) on subunit mRNAs of N-methyl-D-aspartate (NMDA) receptors (NR1/NR2A-2C) in the rat brain by in situ hybridization using phosphor screen analysis. The level of NR1 subunit mRNA significantly increased in hippocampal complexes 1 h after a single i.p. injection of cocaine. After repeated cocaine injection, the mean scores of stereotyped behavior were increased with the number of injections. The level of NR1 subunit mRNA was obviously decreased in the striatum and cortices 24 h (early withdrawal) after a final injection following 14 days of subchronic administration. During the early withdrawal period, the amount of the NR1 subunit decreased in the nucleus accumbens, globus pallidus, and subiculum. In the dentate gyrus, the NR1 mRNA level significantly increased during early withdrawal in rats subchronically treated with cocaine. Levels of NR2B subunit mRNA were reduced in the cortices and striatum. During late withdrawal from cocaine, the level of NR2C subunit mRNA in the cerebellum was also reduced. These findings suggest that the disruption of NR1, NR2B, and NR2C subunits in the discrete brain regions occurs under the cocaine-related behavioral abnormalities and would be closely implicated in the initiation and expression of behavioral sensitization induced by repeated cocaine administration. Further studies on the changes in non-NMDA receptors are required to elucidate the biological significance of glutamate receptors for the mechanisms underlying the development of behavioral sensitization.     

Drugs of Abuse, Immune Modulation, and AIDS

Illicit drugs such as amphetamines, cocaine, marijuana, and opiates alter immune function and decrease host resistance to microbes in vitro and in experimental animal models. Effects on the immune system may be mediated indirectly as a result of drug interactions in the central nervous system (CNS) or directly through activation of cognate receptors on various immune cell types. For marijuana and opioids, seven-transmembranal G protein-coupled receptors have been identified in the CNS and in the immune system that may play a functionally relevant role in immune modulation. There is accumulating evidence that sigma₁ receptors play a comparable role in cocaine-mediated alteration of immune responses. A mode by which these exogenously introduced substances affects immunity and host resistance may be by perturbing the balance of Th₁ proinflammatory versus Th₂ anti-inflammatory cytokines and lipid bioeffectors. However, while illicit drugs have been documented to alter immune functions in vitro and in animal models, there is a paucity of controlled longitudinal epidemiological studies that definitively correlate immunosuppressive effects with increased incidence of infections or immune disorders in humans, including infection with the human immunodeficiency virus (HIV) or disease progression to AIDS.     

Dopamine-independent action of cocaine on striatal and accumbal neurons

Increasing evidence suggests that dopamine (DA) mechanisms alone cannot fully explain the psychoemotional and behavioural effects of cocaine, including its ability to induce drug-taking behaviour. Although it is known that cocaine, after intravenous administration or smoking, may reach brain levels high enough to inhibit Na+ transport, the role of this action remains unclear. To examine the contribution of local anaesthetic and DA mechanisms to changes in striatal and accumbal neuronal activity induced by cocaine, single-unit recording was combined with iontophoresis in awake, unrestrained rats. Most spontaneously active and glutamate-stimulated neurons were highly sensitive to brief cocaine applications (0-40 nA); cocaine-induced inhibitions occurred at small ejection currents (0-5 nA), were dose-dependent, highly stable during repeated applications and strongly dependent on basal activity rates. These neuronal responses remained almost unchanged after systemic administration of either a selective D1 antagonist (SCH-23390, 0.2 mg/kg) or a combination of SCH-23390 (1 mg/kg) and eticlopride (1 mg/kg), a D2 antagonist. Whereas SCH-23390 alone had a weak attenuating effect, no effect and even a slight enhancement of responses to cocaine occurred in fast-firing glutamate (GLU)-stimulated units after the combined blockade of D1 and D2 receptors. Responses to cocaine were mimicked by iontophoretic procaine (0-40 nA), a short-acting local anaesthetic with minimal effect on DA uptake. Procaine-induced inhibitions occurred at the same low currents, had a similar time-course, and were also strongly dependent on basal discharge rate. Our data support the existence of a DA-independent mechanism for the action of cocaine involving a direct interaction with Na+ channels. Although further studies are required to clarify this mechanism and its interaction with other pharmacological and behavioural variables, a direct interaction with Na+ channels may contribute to changes in neuronal activity induced by self-injected cocaine, thereby playing a role in mediating the psychoemotional and behavioural effects of this drug.     

Long-term oscillation of corticosterone following intermittent cocaine

Summary. We have shown that repeated administration of cocaine, as well as other drugs and nondrug stressors, can induce alternating increases and decreases in several neurotransmitter and endocrine endpoints, which we call oscillation. Oscillation studies have typically used 3–4 pretreatments with cocaine or other agents, raising the question of whether oscillation lasts beyond this point. Using plasma corticosterone as our endpoint measure, we therefore inquired whether oscillation would persist across eight administrations of cocaine over a 28-day period. We report oscillation of corticosterone levels persisting across all eight cocaine groups. Our data also indicate that the degree of oscillation increases with the intertreatment interval. Received May 4, 1999; accepted August 24, 1999     

Injection of the protein kinase inhibitor H7 into the A10 dopamine region blocks the acute responses to cocaine: Behavioral and in vivo microdialysis studies

Cocaine produces a motor-stimulant response in part by its actions within the mesolimbic dopamine system. Repeated exposure to cocaine induces an augmented motor activity response which is termed behavioral sensitization, or reverse tolerance. Previous studies have suggested that sensitization may result from increased dopamine neuronal activity in the A10 region; the origin of the mesolimbic dopamine system. However, the exact mechanisms involved in the development of behavioral sensitization remain to be elucidated. Studies on other forms of sensitization in the nervous system suggest a critical role for increased protein kinase C (PKC) activity in the development of the sensitized response. As a first step in examining the role of PKC in cocaine-induced behavioral sensitization, the effect of intra-A10 administration of a PKC inhibitor, H7, on the acute motor-stimulant response to cocaine was studied. Intra-A10 injections of H7 dose-dependently (1.0–30.0 nmol/side) inhibited cocaine (15.0 mg/kg)-induced motor activity. Pretreatment with H7 (30.0 nmol/side) also blocked the cocaine-induced rise of extracellular dopamine in a terminal region of the mesolimbic dopamine system, the nucleus accumbens, as measured by in vivo microdialysis. These data suggest that activation of protein kinases may be important in cocaine-induced motor activity.     

Discriminative stimulus properties of cocaine and d-amphetamine,and antagonism by haloperidol: A comparative study

This paper presents a comparative study of the discriminative stimulus properties of cocaine and d-amphetamine in the rat. Using a discrete-trial, food-reward, two-lever drug discrimination procedure, one group of rats (n = 7) were trained to discriminate 10 mg/kg cocaine from saline, whereas 1.25 mg/kg d-amphetamine served as a cue to a second group (n = 6). Following training, stimulus generalization gradients were determined for cocaine and d-amphetamine in both groups, and so were the antagonistic effects of haloperidol vs the training drug conditions. The results indicate that the acquisition of discrimination proceeded at a comparable rate in the two groups. In both groups, d-amphetamine was about 5 times more potent than cocaine, and individual threshold doses for the two drugs showed a significant correlation. Haloperidol appeared equally effective in antagonizing 1.25 mg/kg d-amphetamine and 10 mg/kg cocaine. These findings converge to suggest that to a large extent the cueing properties of d-amphetamine and cocaine are similar.     

Recognition of psychostimulants, antidepressants, and other inhibitors of synaptic neurotransmitter uptake by the plasma membrane monoamine transporters

The plasma membrane monoamine transporters terminate neurotransmission by removing dopamine, norepinephrine, or serotonin from the synaptic cleft between neurons. Specific inhibitors for these transporters, including the abused psychostimulants cocaine and amphetamine and the tricyclic and SSRI classes of antidepressants, exert their physiological effects by interfering with synaptic uptake and thus prolonging the actions of the monoamine. Pharmacological, biochemical, and immunological characterization of the many site-directed, chimeric, and deletion mutants generated for the plasma membrane monoamine transporters have revealed much about the commonalities and dissimilarities between transporter substrate, ion, and inhibitor binding sites. Mutations that alter the binding affinity or substrate uptake inhibition potency of inhibitors by at least 3-fold are the focus of this review. These findings are clarifying the picture regarding substrate uptake inhibitor/transporter protein interactions at the level of the drug pharmacophore and the amino acid residue, information necessary for rational design of novel medications for substance abuse and a variety of psychiatric disorders.     

Evidence for the outward transport of norepinephrine in synaptic vesicles attached to the plasma membrane

In a low-sodium, choline⁺ (Ch⁺) medium, rat heart slices, that were labelled in vivo with [³H]norepinephrine, exhibited a delayed, Ca²⁺-dependent release of radioactivity, these radioactive compounds consisted of both amines and deaminated metabolites. The Ca²⁺-dependent release of radioactivity was largely blocked by cocaine suggesting that the release may represent an outward transport of [³H]amines. Reserpine, which is known to inhibit binding of norepinephrine to synaptic vesicles, stimulated the release of deaminated metabolites and some amines from the slices. Cocaine increased the release of [³H]amines in monoamine oxidase inhibited, reserpinized slices in the control medium. When Ch⁺ -Ca²⁺ and reserpine stimulation were combined, the effects of Ch ⁺ -Ca²⁺ predominated. These effects were blocked by cocaine, which then permitted the response to reserpine to become established. The conclusion derived from the above experiments is that norepinephrine coming from synaptic vesicles brought in close proximity to the plasma membrane by a Ca²⁺-dependent system can be transported outwardly to the extraneuronal space by a cocaine-sensitive mechanism.     

Acute administration of SB-277011A, NGB 2904, or BP 897 inhibits cocaine cue-induced reinstatement of drug-seeking behavior in rats: role of dopamine D3 receptors

Recent studies have shown that the novel dopamine (DA) D3 receptor antagonists SB-277011A and NGB 2904 inhibit cocaine- and/or stress-induced reinstatement of drug-seeking behavior. The present study sought to determine if SB-277011A, NGB 2904, or BP-897 (a mixed D3 agonist/antagonist) similarly inhibit cocaine-associated cue-induced reinstatement of drug-seeking behavior. Long-Evans rats were allowed to self-administer cocaine. Each cocaine infusion was paired with discrete conditioned cue-light and tone. Subsequently, drug-seeking (i.e., lever-pressing) behavior was extinguished in the absence of cocaine and cocaine-associated cues. Rats were then tested for cue-induced reinstatement of drug-seeking. We found that cocaine-associated cues evoked robust reinstatement of lever-pressing. Acute intraperitoneal (i.p.) administration of SB-277011A (6, 12, or 24 mg/kg) produced a dose-dependent inhibition of cue-induced reinstatement of drug-seeking behavior by 35, 65, and 85%, respectively, compared to vehicle-treated animals. Acute i.p. administration of NGB 2904 (0.1, 1.0, or 5.0 mg/kg) produced a 45, 30, and 70% inhibition of cue-induced reinstatement, respectively, compared to vehicle-treated animals. Acute i.p. administration of either 0.1 or 1 mg/kg of BP 897 did not produce a significant effect on cue-induced reinstatement, whereas a dose of 3 mg/kg produced a 70% inhibition of cue-induced reinstatement. These findings, combined with previous data, suggest that DA D3 receptor antagonism may underlie the inhibitory effects of SB-277011A and NGB 2904 on cocaine cue-induced reinstatement, while the effects of BP 897 may involve D3 and non-D3 receptor mechanisms.