Differential effects of adenosine antagonists in two models of parkinsonian tremor.

Adenosine A(1) and A(2A) receptors are colocalized with dopamine D(1) and D(2) receptors on striatal projection neurons and adenosine antagonists have been proposed as adjunctive therapies to l-DOPA treatment in Parkinson patients. We present here two studies examining the effects of selective and non-selective adenosine antagonists in two rodent models of parkinsonian tremor. Tremulous jaw movements (TJMs) were induced by either the dopamine antagonist pimozide (1.0 mg/kg) or the acetylcholine agonist tacrine (5.0 mg/kg), and were quantified by a trained observer who was blind to the treatment conditions. Animals were treated concomitantly with either caffeine (10.0 mg/kg non-selective adenosine antagonist), 8-cyclopentyltheophylline (CPT; 10.0 mg/kg; selective A(1) antagonist) or SCH58261 (8.0 mg/kg; selective A(2A) antagonist). Caffeine, CPT and SCH58261 all significantly reduced pimozide-induced TJM activity. Surprisingly administration of adenosine antagonists did not reduce tacrine-induced TJMs, and in the case of SCH58261 significantly increased TJMs compared to tacrine alone. These results indicate that antagonism at A(1) receptors may be more important for the reduction of tremor than previously supposed. Furthermore they indicate that dopamine antagonist-induced tremor models and acetylcholine agonist-induced tremor models are not entirely similar, and caution should be taken when using these models to evaluate novel therapeutics.

Substantia nigra pars reticulata is a highly potent site of action for the behavioral effects of the D1 antagonist SCH 23390 in the rat.

RATIONALE: Considerable evidence indicates that dopaminergic drugs, including drugs that act on D1 receptors, exert their effects by actions on forebrain dopamine terminal regions. Nevertheless, anatomical studies also have demonstrated that there is a high concentration of D1 receptors in the substantia nigra pars reticulata (SNr). The D1 receptors in SNr are located largely on the terminals of gamma-aminobutyric acid (GABA)-ergic striatonigral neurons. The present studies were undertaken to determine whether the D1 antagonist SCH 23390 was effective if locally injected into SNr and to compare the results of SNr injections with those obtained from other brain sites. Fixed ratio 5 (FR5) lever pressing and open-field locomotion were used as the behavioral tests because these tasks are sensitive to systemic SCH 23390. METHODS: Rats received bilateral implantations of guide cannulae into either nucleus accumbens, neostriatum, SNr, or control sites in the cortex or brainstem. Rats in the FR5 study were trained prior to surgery. All rats received one of the following local injections (0.5 microl per side): vehicle, 0.25, 0.5, 1.0, or 2.0 microg SCH 23390. RESULTS: In the FR5 study, the SNr was by far the most potent site for suppression of lever pressing, with an ED50 (dose that produces half maximal response) of 0.33 microg per side. Nucleus accumbens and neostriatum injections were less potent than those in SNr, but more potent than injections into the control regions. With open-field locomotion, the SNr, nucleus accumbens, and neostriatum were approximately equipotent sites, and all three were more potent than the control sites. CONCLUSIONS: SNr was a very potent site for suppression of lever pressing and open-field locomotion. These data suggest that D1 antagonists have multiple sites of action, including not only the forebrain dopamine terminal regions but also the SNr. It is possible that blockade of SNr D1 receptors modulates GABA release from striatonigral neurons.

Effects of H1 antagonists on cholinomimetic-induced tremulous jaw movements: studies of diphenhydramine, doxepin, and mepyramine.

In several previous studies, tremulous jaw movements in rats have been used to assess the effects of antiparkinsonian drugs and atypical antipsychotics. Because antihistamines such as diphenhydramine are used as antiparkinsonian agents, and atypical antipsychotic drugs such as clozapine and olanzapine have high affinity for histamine H1 receptors, the present study investigated the effects of H1 antagonists on cholinomimetic-induced jaw movements. Diphenhydramine, doxepin, and mepyramine (all injected IP 2.5-20.0 mg/kg) were assessed for their ability to block the jaw movements induced by 5.0 mg/kg of the anticholinesterase tacrine. Within this dose range, only diphenhydramine produced a robust and significant reduction in jaw movement activity. Thus, diphenhydramine was subjected to further testing, which employed procedures previously used to assess the effects of other antitremorogenic drugs, such as clozapine. Diphenhydramine did not induce jaw movement activity. In addition to suppressing jaw movement activity after acute injections, diphenhydramine also suppressed tacrine-induced jaw movements after repeated (14-day) administration. In summary, the present results show that diphenhydramine suppresses cholinomimetic-induced jaw movements, an effect that is similar to other antiparkinsonian or antitremor drugs such as anticholinergics, L-DOPA, DA antagonists, and clozapine. Nevertheless, doxepin produced only mild effects, and mepyramine, which has a higher affinity and selectivity than diphenhydramine for H1 receptors, failed to suppress cholinomimetic-induced jaw movements. These results suggest that diphenhydramine suppresses tremulous movements through a mechanism that does not depend upon antagonism of histamine H1 receptors.

Behavioral assessment of atypical antipsychotics in rats: studies of the effects of olanzapine (Zyprexa).

RATIONALE: Previous work has shown that clozapine suppressed tacrine-induced jaw movements at lower doses than those required for suppression of lever pressing. OBJECTIVE: The novel atypical antipsychotic olanzapine was assessed in these behavioral tests. METHODS: The effect of acute olanzapine on the suppression of tacrine-induced tremulous jaw movements was examined. In order to determine the relative potency of this effect compared with other behavioral effects of olanzapine, suppression of lever pressing also was studied. In a second series of experiments, rats received olanzapine for 14 consecutive days to study the effects of repeated injections of this drug on jaw movements and lever pressing. RESULTS: Acute olanzapine administration decreased tacrine-induced jaw movements (ED50: 0.4 mg/kg), and also reduced lever pressing (ED50: 1.12 mg/kg). The ratio of the ED50 for suppression of jaw movements to that for suppression of lever pressing was used as an index of liability to produce extrapyramidal side effects, and the present results demonstrate that olanzapine has a ratio similar to that previously shown for clozapine. In the repeated administration studies, rats were observed on day 13 of drug treatment for the ability of olanzapine to induce jaw movements, and olanzapine failed to induce jaw movements. On day 14, olanzapine reduced tacrine-induced tremulous jaw movements (ED50: 1.12 mg/kg). In a separate experiment, olanzapine significantly suppressed lever pressing, and this effect showed sensitization with repeated administration (day 14, ED50: 0.76 mg/kg). Thus, repeated injections of olanzapine reduced tacrine-induced jaw movements in a dose range similar to or slightly higher than that which suppressed lever pressing. CONCLUSIONS: On tests of jaw-movement activity and lever pressing after both acute and repeated drug administration, olanzapine demonstrated a profile somewhat similar to clozapine, and both of these drugs differ substantially from the typical antipsychotic haloperidol.

Nucleus accumbens dopamine depletions and time-constrained progressive ratio performance: effects of different ratio requirements.

Two experiments were conducted to determine the effects of accumbens dopamine (DA) depletions on progressive ratio responding for food reinforcement. In one version of this schedule, ratio requirement increased by one response after each reinforcer was obtained (PROG1). In the other version, ratio requirement increased by five responses after each reinforcer was obtained (PROG5). For both versions, 60-min sessions were conducted. Accumbens DA depletions produced by local injections of 6-OHDA substantially decreased the number of responses on both schedules. The deficits in the response number induced by DA depletions persisted through the two weeks of postsurgical testing for both the PROG1 and PROG5 schedules. However, there were differences between the effects of DA depletions on the two schedules in terms of the time to complete the last ratio. Although time to complete the last ratio was significantly reduced by DA depletions only in the first week of testing on the PROG1 schedule, rats recovered on this measure by the second week after surgery. In contrast, DA-depleted rats on the PROG5 schedule showed a more persistent suppression of the time to complete the last ratio, which lasted through both weeks of postsurgical testing. Performance on schedules that generate low baseline rates of responding (e.g., continuous, fixed, and variable interval) is relatively unaffected by accumbens DA depletions; nevertheless, accumbens DA depletions substantially impair progressive ratio response output. The high work output necessary for responding on the PROG5 schedule may make these animals more sensitive to the effects of accumbens DA depletions.

Different behavioral functions of dopamine in the nucleus accumbens and ventrolateral striatum: a microdialysis and behavioral investigation.

Three experiments were conducted to investigate the behavioral functions of dopamine in the nucleus accumbens and ventrolateral striatum. In the first experiment, dialysis probes were implanted in the nucleus accumbens or ventrolateral striatum of rats previously trained to respond on fixed interval lever pressing schedules for food reinforcement. During the dialysis test session, both schedule- and site-dependent effects on dopamine release were observed. Overall, lever pressing on a fixed interval 30-s schedule produced a greater increase in extracellular dopamine than did responding on a fixed interval 120-s schedule. The fixed interval 30-s schedule was also accompanied by a higher rate of lever pressing. Rats with nucleus accumbens probe placements showed significantly higher increases in dopamine release than rats with ventrolateral striatal placements. An additional dialysis experiment showed that baseline levels of dopamine were suppressed by 1.0 microM tetrodotoxin to a similar extent in the nucleus accumbens and ventrolateral striatum. In the third experiment, 6-hydroxydopamine was injected locally into either the nucleus accumbens or the ventrolateral striatum in order to deplete dopamine. Nucleus accumbens dopamine depletions produced only a minor decrease in operant responding, whereas rats with ventrolateral striatal dopamine depletions showed low levels of responding that differed from both the control group and from the group that had accumbens dopamine depletions. Thus, these results are somewhat paradoxical, in that the structure that showed the greatest increase in dopamine release (i.e. the nucleus accumbens) was also the terminal region at which dopamine depletions had very little effect on operant responding. Ventrolateral striatal dopamine appears to be largely permissive over lever pressing, in that normal levels of dopamine in the ventrolateral striatum are critical for responding, although dopamine levels do not fluctuate much during behavioral sessions.

Striatal and nigral D1 mechanisms involved in the antiparkinsonian effects of SKF 82958 (APB): studies of tremulous jaw movements in rats.

RATIONALE: Previous work has demonstrated that cholinomimetic-induced tremulous jaw movements in rats have temporal and pharmacological characteristics similar to parkinsonian tremor. OBJECTIVE: This rodent model was used to characterize the putative antiparkinsonian effects of the full D1 dopamine receptor agonist, SKF 82958. METHODS: Jaw movement activity was induced by the muscarine agonist pilocarpine (4.0 mg/kg IP), and a series of experiments studied the pharmacological characteristics of the reversal of pilocarpine-induced jaw movements by SKF 82958. RESULTS: SKF 82958 (0.5-2.0 mg/kg IP) reduced the tremulous jaw movements induced by pilocarpine. The suppressive effects of SKF 82958 on jaw movements were dose-dependently reversed by systemic pretreatment with the selective D1 dopamine receptor antagonist SCH 23390 (0.025-0.2 mg/kg IP); SCH 23390 was about 16 times more potent than the D2 antagonist raclopride at reversing the effects of SKF 82958. Intracranial injection of SCH 23390 (0.5-2.0 micrograms/side) into the ventrolateral striatum, the rodent homologue of the human ventral putamen, dose-dependently reversed the reduction of pilocarpine-induced jaw movements produced by SKF 82958. Intracranial injection of SCH 23390 (0.5-2.0 micrograms/side) into the substantia nigra pars reticulata also dose-dependently reversed the reduction by SKF 82958 of pilocarpine-induced jaw movements. Injections of SCH 23390 (2.0 micrograms/side) into control sites dorsal to the striatum or substantia nigra had no effects on the action of SKF 82958. Intranigral (SNr) injections of the GABA-A antagonist bicuculline blocked the suppressive effect of systemically administered SKF 82958 on jaw movement activity. CONCLUSIONS: These data suggest that the antiparkinsonian actions of SKF 82958 may be due to stimulation of D1 receptors in the ventrolateral striatum and substantia nigra pars reticulata. In addition, these results indicate that GABA mechanisms in the substantia nigra pars reticulata may be important for the antiparkinsonian effects of D1 agonists.

The role of ventrolateral striatal acetylcholine in the production of tacrine-induced jaw movements.

The anticholinesterase tacrine induces tremulous jaw movements in rats, and considerable evidence indicates that this response is dependent upon ventrolateral striatal mechanisms. Three experiments were conducted to study the relation between ventrolateral striatal acetylcholine and the production of tremulous jaw movements. In Experiment 1, intracranial microinjection of the acetylcholine synthesis inhibitor hemicholinium-3 into the ventrolateral neostriatum reduced tremulous jaw movements induced by 5.0 mg/kg tacrine. Microinjection of hemicholinium into a cortical site dorsal to striatum (Experiment 2) was without significant effect upon tacrine-induced tremulous jaw movements. In Experiment 3, rats were implanted with dialysis probes in the ventrolateral striatum to measure extracellular levels of acetylcholine during tacrine-induced jaw movements. Tacrine (2.5-5.0 mg/kg) increased both extracellular acetylcholine and tremulous jaw movements. The 5.0 mg/kg dose of tacrine produced a substantial increase in ventrolateral striatal acetylcholine levels (324% of baseline within 30 min). Across all tacrine-treated rats there was a significant linear correlation between tremulous jaw movements and acetylcholine levels (r = +0.56) during the first 30-min postinjection period. This correlation was largely due to the group that received 5.0 mg/kg tacrine; within this group, there was a very high correlation (r = +0.87) between tremulous jaw movements and acetylcholine levels in the first sample after injection. These data are consistent with the notion that tremulous jaw movements induced by tacrine are mediated by ventrolateral striatal acetylcholine. Moreover, these results suggest that dialysis methods could be used to monitor the relation between striatal acetylcholine and tremulous movements induced by a variety of different conditions.

Characterization of the muscarinic receptor subtype mediating pilocarpine-induced tremulous jaw movements in rats.

Four muscarinic receptor antagonists with varying selectivities for the four pharmacologically-defined muscarinic receptor subtypes (M1-M4) were administered into the lateral ventricle to determine their relative potency in reducing tremulous jaw movements induced by i.p. injection of the muscarinic receptor agonist pilocarpine (4.0 mg/kg). All four muscarinic receptor antagonists reduced tremulous jaw movements in a dose-dependent manner, with the following rank order of potency: scopolamine > methoctramine > or = telenzepine > pirenzepine. This pattern is inconsistent with the rank order of affinity of these agents at the muscarinic M1 receptor, and is consistent with their rank order of affinity at muscarinic M2 or M4 receptors. Because tremulous jaw movements are related to striatal function, and the muscarinic M4 receptor is more predominant than the muscarinic M2 receptor as a post-synaptic receptor in striatum, the present results suggest that pilocarpine induces jaw movements due to muscarinic M4 receptor stimulation. In view of the hypothesized relation between parkinsonism and cholinomimetic-induced jaw movements, these data suggest that a centrally-acting muscarinic M4 receptor antagonist could be useful as an antiparkinsonian agent.

Effects of subchronic administration of clozapine, thioridazine and haloperidol on tests related to extrapyramidal motor function in the rat.

Clozapine, thioridazine (THIO) and haloperidol were administered for 14 consecutive days, and separate groups of rats were used to study the effects of these drugs on tremulous jaw movements and lever pressing. Rats were observed on day 13 for the ability of the antipsychotic drugs to induce jaw movements. Haloperidol produced a dose-related increase in jaw movements, while clozapine and THIO failed to induce jaw movements. On day 14, rats were challenged with 5.0 mg/kg of the anticholinesterase tacrine, which induces a very high level of jaw movement activity. Clozapine significantly reduced tacrine-induced tremulous jaw movements, while haloperidol did not. Although previous work had shown that acute THIO could suppress jaw movements, repeated THIO failed to do so. In order to provide an additional behavioral test for comparisons of the relative potencies of the antipsychotic drugs, rats were tested for the effects of these drugs on fixed ratio 5 lever pressing. All three drugs significantly suppressed lever pressing. Haloperidol showed sensitization with repeated injections, while clozapine showed tolerance. Data were analyzed by taking the ratio of the ED50 for suppression of tacrine-induced jaw movement over the ED50 for suppression of lever pressing on day 14. Clozapine reduced tacrine-induced jaw movements in a dose range slightly lower than that required for reduction of lever pressing. In contrast, THIO and haloperidol failed to affect tacrine-induced jaw movements even at doses that were 5-18 times the ED50 for suppression of lever pressing. Thus, tests of jaw movement activity and lever pressing after repeated administration may be useful for assessing atypical antipsychotic drugs.

Tremulous jaw movements in rats: a model of parkinsonian tremor.

Several pharmacological and neurochemical conditions in rats induce 'vacuous' or 'tremulous' jaw movements. Although the clinical significance of these movements has been a subject of some debate, considerable evidence indicates that the non-directed, chewing-like movements induced by cholinomimetics, dopamine antagonists and dopamine depletions have many of the characteristics of parkinsonian tremor. These movements occur within the 3-7 Hz peak frequency range that is characteristic of parkinsonian tremor. Tremulous jaw movements are induced by many of the conditions that are associated with parkinsonism, and suppressed by several different antiparkinsonian drugs, including scopolamine, benztropine, L-DOPA, apomorphine, bromocriptine, amantadine and clozapine. Striatal cholinergic and dopaminergic mechanisms are involved in the generation of tremulous jaw movements, and substantia nigra pars reticulata appears to be a major basal ganglia output region through which the jaw movements are regulated. Future research on the neurochemical and anatomical characteristics of tremulous jaw movements could yield important insights into the brain mechanisms that generate tremulous movements.

Effects of clozapine, thioridazine, risperidone and haloperidol on behavioral tests related to extrapyramidal motor function.

Evidence indicates that the antipsychotic drug clozapine has a low propensity for the induction of extrapyramidal motor symptoms, and also that clozapine has therapeutic effects in patients with idiopathic Parkinson's disease. Because tacrine-induced tremulous jaw movements in rats have been suggested as a possible model of extrapyramidal motor dysfunctions, including parkinsonian tremor, the present work was undertaken to investigate the effects of clozapine on tremulous jaw movements. Clozapine decreased tacrine-induced tremulous jaw movements in a dose-related manner, with an ED50 of approximately 3.3 mg/kg. In order to determine the relative potency of this effect compared to other behavioral effects of clozapine, suppression of lever pressing was also studied. Clozapine reduced lever pressing in a dose-related manner, with an ED50 of approximately 5.4 mg/kg. This indicates that clozapine suppressed jaw movements at or below the doses required for suppression of lever pressing. In contrast, the typical antipsychotic drug haloperidol failed to suppress tacrine-induced tremulous jaw movements in doses up to 1.0 mg/kg, which is about 11-fold higher than the ED50 for suppression of lever pressing with that drug. Thioridazine and risperidone also suppressed tremulous jaw movements in roughly the same dose range at which lever pressing was reduced. It is possible that the suppression of tacrine-induced tremulous jaw movements by clozapine in rats is related to the unique behavioral and motor effects of clozapine. The ratio of potencies of these effects (i.e., suppression of tremulous jaw movements versus suppression of lever pressing) could be used as a behavioral procedure for assessing clozapine-like activity in novel compounds.