Metabolite involvement in bromocriptine-induced circling behaviour in rodents

The neurobiology of the substantia nigra pars compacta: from motor to sleep regulation

Clinical characteristics of Parkinson's disease (PD) are the result of the degeneration of the neurons of the substantia nigra pars compacta (SNpc). Several mechanisms are implicated in the degeneration of nigrostriatal neurons such as oxidative stress, mitochondrial dysfunction, protein misfolding, disturbances of dopamine (DA) metabolism and transport, neuroinflammation, and necrosis/apoptosis. The literature widely explores the neurotoxic models elicited by 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) and 6-hydroxydopamine (6-OHDA). Because of the models, it is known that basal ganglia, particularly substantia nigra, have been related to a diversity of functions, from motor to sleep regulation. Nevertheless, a current debate concerning the role of DA on the sleep-wake cycle is in progress. In summary, it is suggested that the dopaminergic system is implicated in the physiology of sleep, with particular regard to the influence of the SNpc neurons. The understanding of the functioning and connectivity of the SNpc neurons has become fundamental to discovering the neurobiology of these neurons.

Microdialysis study of bromocriptine and its metabolites in rat pituitary and striatum

Bromocriptine, a D2 receptor agonist, was administered intravenously (1mg/kg) to anesthetized rats. Microdialysis probes were implanted in the pituitary and the striatum, known sites of D2 agonist action. Bromocriptine and its metabolites were monitored in plasma and tissue dialysates for 4 h. Drug analyses were performed using two different enzyme immunoassays specific for untransformed bromocriptine or a pool of parent drug plus hydroxylated metabolites. The metabolites/parent drug ratio for areas under the curve was 5.5 in plasma and 1 in the pituitary. No metabolites could be detected in the striatum. Bromocriptine penetration was at least 10-fold greater in the pituitary than in the striatum. The kinetics of bromocriptine in the pituitary and striatum did not parallel those in plasma, indicating that the prolonged action of bromocriptine reported by other authors may be due to slow dissociation from receptors.

Different effects of direct and indirect dopamine receptor agonists on immobility time in reserpine-treated mice

1. The effects of dopamine agonists on the immobility time in mice were examined. 2. Apomorphine (APO), bupropion (BUP), bromocriptine (BRC) and quinpirole but not SKF 38393 elicited anti-immobility effect. The effect of the agonists was decreased by the D-2 antagonist sulpiride but not by the D-1 antagonist SCH 23390. 3. In animals pretreated with reserpine, the anti-immobility effects of APO and quinpirole were potentiated, while the response of BPU was decreased and that of BRC was not changed. 4. It is concluded that D-2 dopamine receptors are involved in the anti-immobility effects of dopaminergic agents, D-2 dopamine receptors may become hypersensitive by reserpine and BUP exerts its response through indirect dopaminergic if mechanism.

Metabolite involvement in the behavioral effects of bromocriptine in cats

There is a lag phase of 30-60 min before the onset of bromocriptine (BC) action. This delay may be necessary for the formation of active metabolites. The objective was to determine whether the abnormal behavioral effects induced by BC involve active hepatic metabolites. Thus, we studied the effect of an inhibitor of hepatic hydroxylation metabolism (SKF 525A) on the behavior of BC-treated cats. Experiments began after six weeks of habituation and involved i.p. injections of: (1) propylene glycol (drug vehicle); (2) SKF 525A (70 mg/kg); (3) BC (10 mg/kg); and (4) SKF 525A followed 30 min later by BC. Each cat received the four treatments with two weeks elapsing between consecutive experiments. The frequency of 12 behaviors was scored for 60 min after 1 h posttreatment. BC alone induced emergent behavioral changes (hallucinatory-like, limb flicks, abortive grooms) that were not observed following control injections (vehicle and SKF 525A). There was a complete elimination of BC-induced hallucinatory-like behavior/escape by SKF 525A pretreatment. Other emergent behaviors were similarly reduced but persisted in all cats. The large frequency of grooming induced by BC was significantly reduced. SKF 525A pretreatment was correlated with a significant increase in staring and quiet sitting and a failure of BC to increase activities such as rubbing, treading and kneading. But many other BC-induced behaviors showed no changes. The data demonstrated that particular BC-induced changes in cats are antagonized by SKF 525A. The behavioral suppression caused by SKF 525A is compatible with the involvement of active hepatic metabolites from BC.(ABSTRACT TRUNCATED AT 250 WORDS)

Bromocriptine-induced locomotor stimulation in mice is modulated by dopamine D-1 receptors

Mice were pretreated with reserpine plus alpha-methyl-p-tyrosine (10 mg/kg plus 200 mg/kg). One hour later they were administered the selective dopamine D-2 agonist bromocriptine or vehicle. Three hours after the bromocriptine, mice were challenged with the selective D-1 agonist SKF 38393, and locomotor activity was measured each 5 min for three hours. Neither bromocriptine nor SKF 38393 produced significant stimulation. The combination, however, produced a dose-dependent and coordinated increase in activity. If the bromocriptine was given only one hour before the SKF 38393 challenge (i.e., three hours after the reserpine plus alpha-methyl-p-tyrosine), no interaction was seen. In naive mice, when SKF 38393 and bromocriptine were administered together, the locomotor response to bromocriptine was quantitatively and qualitatively altered. The initial depressant response to bromocriptine was shortened, producing a more rapid onset of the stimulant response. In one experiment, the maximal activity induced by bromocriptine was increased by SKF 38393. The ability of SKF 38393 to alter the locomotor stimulant effect of bromocriptine in naive mice was blocked by their pretreatment with the selective D-1 antagonist, SCH 23390. The data indicate that the locomotor stimulant effects of bromocriptine are modulated by D1 receptors.

Bromocriptine enhances the behavioural effects of apomorphine and dopamine after systemic or intracerebral injection in rats

The ergot alkaloid bromocriptine, given intraperitoneally produced dose-dependent, long-lasting stereotyped behaviour in rats which was partly antagonised by the injection of trifluoperazine into the caudate nucleus. The stereotyped behaviour produced by apomorphine (s.c.) in both naïve and catecholamine-depleted rats was significantly enhanced by prior treatment with bromocriptine (i.p.). The bilateral application of bromocriptine (2.5-40 micrograms/side in either 0.5% tartaric acid or 50% propylene glycol aqueous vehicles) to the nucleus accumbens (NAC) of rats had no effect on locomotion over a 12 hr period after injection. In contrast, another ergot alkaloid, ergometrine, dissolved in the propylene glycol vehicle, and dopamine (DA) dissolved in either of the vehicles or in saline, produced marked stimulation of locomotion. As well as being inactive after direct application to the nucleus accumbens, bromocriptine (10-160 micrograms/side) did not induce stereotyped behaviour after bilateral injection into the caudate nucleus. However, the local application of bromocriptine (10 micrograms/side) to the nucleus accumbens, while itself inactive, significantly enhanced the locomotor stimulant effect of DA (5 micrograms/side) applied to the same nucleus. The data suggest that bromocriptine is able to enhance the effects of agonists such as DA and apomorphine at DA receptors, even under conditions where bromocriptine itself is inactive.

Bromocriptine potentiates the behavioural effects of directly and indirectly acting dopamine receptor agonists in mice

After an initial period of depression which lasted up to 90 min following injection, bromocriptine (BRC, 5-20 mg/kg, IP) produced dose-dependent and long lasting (7 h) locomotor stimulation in mice. The locomotor stimulation was antagonised by reserpine, alpha-methyl-p-tyrosine (AMPT) or haloperidol. The blockade by AMPT of BRC's locomotor stimulant effect was reversed by prior treatment of the mice with a low, behaviourally inactive dose of L-Dopa plus benserazide. In mice pretreated with reserpine, BRC enhanced the stimulant action of d-amphetamine. Moreover, in mice pretreated with reserpine plus AMPT, BRC significantly enhanced the locomotor stimulant effect of apomorphine. This ability of BRC to enhance the effect of apomorphine commenced as soon as 20 min after BRC administration and lasted for at least 8 h. The dopamine (DA) uptake inhibitor and DA receptor agonist nomifensine potentiated and prolonged the stimulant effect of BRC while inhibitors of the neuronal uptake of noradrenaline (desipramine) and 5-hydroxytryptamine (fluoxetine) were without marked effect. The results clearly show that BRC, in behavioural terms, has no efficacy per se at the postsynaptic DA receptor and that it requires either DA or the administration of an exogenous agonist such as apomorphine for the expression of its effects.

Hypothesis: bromocriptine lacks intrinsic dopamine receptor stimulating properties

Bromocriptine (BRC) produced neither locomotor stimulation nor stereotyped behavior in mice and rats pretreated with reserpine plus alpha-methyl-p-tyrosine (AMPT). However, the blockade of locomotor stimulation in mice by AMPT could be reversed by their prior treatment with a low, behaviorally inactive dose of L-DOPA. BRC potentiated the stereotypy (rats) and locomotor stimulation (mice) produced by apomorphine in animals pretreated with reserpine plus AMPT. Moreover, BRC potentiated the stimulant effect of d-amphetamine in reserpinized mice, while nomifensine, but not fluoxetine or desipramine, potentiated the stimulant effect of BRC in mice. After direct application to the nucleus accumbens or caudate nucleus of rats, BRC was inactive. However, when BRC and DA were applied together to the nucleus accumbens, BRC enhanced the stimulant effect of DA. These data show that BRC by itself does not cause behavioral stimulation in rodents. Despite having affinity for the DAD 2-receptor, BRC is incapable of causing excitation in rats and mice unless another DA-receptor agonist such as apomorphine or DA is present. The data are discussed in relation to the published literature and the hypothesis presented that BRC affects the signal transmitted by DA-receptor agonists such as apomorphine at or beyond the postsynaptic DA-receptor.

Multiple dopamine receptors and behavior

The therapeutic effects of dopamine (DA) agonists and DA antagonists used in the treatment of schizophrenia (antipsychotics, DA antagonists), Huntington's chorea (DA antagonists) and Parkinson's disease (antiparkinsonian agents, DA agonists) have been thought to result largely from actions on DA receptors located in the striatum (caudate nucleus and putamen). Many of the classical drugs used to treat these disorders are known to have a high incidence of extrapyramidal side effects (EPS). However, a number of drugs, the atypical antipsychotics and antiparkinsonian agents, have been developed which have a low incidence of EPS. It has been of enormous interest to researchers and clinicians alike to determine what characteristics of the atypical antipsychotics and antiparkinsonian agents are responsible for their unique behavioral profile. Because all of the antipsychotics and antiparkinsonian agents act on DA receptors, much attention has focused on potential differences in the interactions of the atypical agents with DA receptors. An hypothesis that has been raised, due to the knowledge that there are multiple subtypes of DA receptors located in the striatum, is that the atypical agents could have their therapeutic actions as a result of an interaction with one specific subtype of DA receptor. This review emphasizes two major points: (1) it is unlikely that the atypical antipsychotics and antiparkinsonian agents interact with only one subtype of DA receptor, or have their therapeutic actions only through that receptor; (2) other pharmacological characteristics of these agents are more critically involved in their unique behavioral effects. The applicability of animal models to assess the pharmacological and behavioral profiles of these agents is discussed, and the relevance to the clinical profiles of these agents is emphasized.

Bromocriptine inhibits 2-deoxy-D-glucose-stimulated gastric acid secretion in the rat

The influence of bromocriptine on the secretagogue-induced gastric acid secretion was examined in rats. The drug inhibited the gastric acid secretion centrally stimulated by 2-deoxy-D-glucose (2DG) in anesthetized or conscious rats. Apomorphine also prevented 2DG-induced acid secretion in anesthetized rats but not in conscious rats. Neither bromocriptine nor apomorphine significantly influenced the acid secretion induced peripherally by electrical vagus stimulation or gastrin. The antisecretory effect of bromocriptine was reversed by dopamine antagonists in anesthetized or conscious rats, but not by apomorphine in anesthetized rats. The results suggest that in rats, the antisecretory effect of bromocriptine on 2DG-stimulated acid secretion is partly due to its central dopamine agonistic action, but that of apomorphine may be due to dopaminergic plus other mechanisms.

Differentiation of dopamine agonists using drug-induced rotation in rats with unilateral or bilateral 6-hydroxydopamine destruction of ascending dopamine pathways

Eighteen compounds with dopamine agonist properties were examined in two rat rotational models. In the classical Ungerstedt model, a unilateral 6-hydroxydopamine (60HDA) lesion destroyed nigrostriatal and mesolimbic dopamine pathways on one side. Indirectly acting compounds, amphetamine, amantadine, methylphenidate and S1694, produced ipsiversive rotation, which was inhibited by pretreatment with alpha-methyl-p-tyrosine (AMPT). All other compounds produced contraversive rotation, but the rotation caused by CM 29-712, bromocriptine and ET 495 was reduced by AMPT. In animals with a bilateral 60HDA lesion removing both dopaminergic inputs to nucleus accumbens and the dopaminergic input into one striatum, indirectly acting drugs caused ipsiversive posturing prevented by AMPT, but little rotation. All other compounds produced contraversive rotation, but the effects of CM 29-712, bromocriptine and ET 495 were reduced by AMPT pretreatment. Inhibition of monooxygenase drug metabolising activity utilising SKF-525A inhibited contraversive turning induced by bromocriptine and ET 495 in the unilateral lesion model, but had no effect on rotation caused by apomorphine or CM 29-712. We conclude that, in addition to indirect pre-synaptically acting agonists and direct post-synaptic receptor agonists, there are a small group of compounds which produce rotation associated with direct receptor activation, which is inhibited by disruption of pre-synaptic dopamine function. The mechanism of action of this latter group is not understood, but cannot be attributed solely to active metabolite formation.

Effects of three dopamine agonists on cage climbing behavior

The effects of three structurally related dopamine (DA) agonists (pergolide, lergotrile, bromocriptine) on motor activity and induction of cage climbing behavior were compared in mice. Pergolide stimulated activity and induced cage climbing that persisted for at least 5 h. Lergotrile depressed activity and failed to induce climbing over a wide range of doses. Bromocriptine produced stimulation and climbing, but only after a 2-3 h delay following injection. The qualitative differences among these drugs may represent an action involving different DA receptor subjects.