Studies on animal models of stress, anxiety, aggression, and sensorimotor gating have linked specific monoamine neurotransmitter abnormalities to the cognitive and behavioral disturbances associated with many affective neuropsychiatric disorders. Although alpha2-adrenoceptors (alpha2-ARs) have been suggested to have a modulatory role in these disorders, the specific roles of each alpha2-AR subtype (alpha2A, alpha2B, and alpha2C) are largely unknown. The restricted availability of relevant animal models and the lack of subtype-selective alpha2-AR drugs have precluded detailed studies in this area. Therefore, transgenic mice were used to study the possible role of the alpha2C-AR subtype in two well established behavioral paradigms: prepulse inhibition (PPI) of the startle reflex and isolation-induced aggression. The alpha2C-AR-altered mice appear grossly normal, but subtle changes have been observed in their brain dopamine (DA) and serotonin (5-HT) metabolism. In this study, the mice with targeted inactivation of the gene encoding alpha2C-ARs (alpha2C-KO) had enhanced startle responses, diminished PPI, and shortened attack latency in the isolation-aggression test, whereas tissue-specific overexpression of alpha2C-ARs (alpha2C-OE) was associated with opposite effects. Correlation analyses suggested that both the magnitude of the startle response and its relative PPI (PPI%) were modulated by the mutations. In addition, the differences in PPI, observed between drug-naive alpha2C-OE mice and their wild-type controls, were abolished by treatment with a subtype nonselective alpha2-agonist and antagonist. Thus, drugs acting via alpha2C-ARs might have therapeutic value in disorders associated with enhanced startle responses and sensorimotor gating deficits, such as schizophrenia, attention deficit disorder, post-traumatic stress disorder, and drug withdrawal.
SUMMARY␣ 2 -Adrenergic receptors (␣ 2 -ARs) regulate many physiological functions and are targets for clinically important antihypertensive and anesthetic agents. Three human and mouse genes encoding ␣ 2 -AR subtypes (␣ 2A , ␣ 2B , and ␣ 2C ) have been cloned. We investigated the involvement of the ␣ 2C -AR in ␣ 2 -adrenergic pharmacology by applying molecular genetic techniques to alter the expression of ␣ 2C -AR in mice. The effects of dexmedetomidine, a subtype-nonselective ␣ 2 -AR agonist, on monoamine turnover in brain and on locomotor activity were similar in mice with targeted inactivation of the ␣ 2C -AR gene and in their controls, but the hypothermic effect of the ␣ 2 -AR agonist was significantly attenuated by the receptor gene inactivation. Correspondingly, another strain of transgenic mice with 3-fold overexpression of ␣ 2C -AR in striatum and other brain regions expressing ␣ 2C -AR showed normal reductions in brain monoamine metabolism and locomotor activity after dexmedetomidine, but their hypothermic response to the ␣ 2 -AR agonist was significantly accentuated. The hypothermic effect of ␣ 2 -AR agonists thus seems to be mediated in part by ␣ 2C -AR. Some small but statistically significant differences between the strains were also noted in brain dopamine metabolism. Lack of ␣ 2C -AR expression was linked with reduced levels of homovanillic acid in brain, and mice with increased ␣ 2C -AR expression had elevated concentrations of the dopamine metabolite compared with their controls.␣ 2 -ARs mediate many physiological functions and pharmacological effects in the central nervous system, mainly by inhibiting neuronal firing and release of NE and other neurotransmitters. ␣ 2 -ARs are also involved in a wide range of functions in peripheral tissues (e.g., in the regulation of NE release from sympathetic nerves, smooth muscle contraction, platelet aggregation, insulin secretion, glomerular filtration, and energy metabolism) (1). Activation of ␣ 2 -ARs with the highly specific ␣ 2 -AR agonist dexmedetomidine results in bradycardia, hypotension, hypothermia, locomotor inhibition, anxiolysis, analgesia, sedation, and, with higher doses, anesthesia. Dexmedetomidine also reduces the turnover of the monoamine neurotransmitters NE, DA, and 5-HT (serotonin) in brain (2).Recent pharmacological and biochemical research has led to a subdivision of ␣ 2 -ARs into three distinct subtypes: ␣ 2A -, ␣ 2B -, and ␣ 2C -ARs. This classification was first based on the pharmacological properties of the receptors and was confirmed through the cloning of three distinct ␣ 2 -AR genes in humans, rats, mice, and other species (3). Each receptor has a distinct tissue distribution. In the central nervous system of the rat, ␣ 2A -ARs are widely expressed, whereas the other ␣ 2 -AR subtypes have more limited distributions. ␣ 2C -ARs are present in the basal ganglia, olfactory tubercle, hippocam-ABBREVIATIONS: AR, adrenergic receptor; DA, dopamine; NE, norepinephrine; MHPG, 3-methoxy-4-hydroxyphenylglycol; HVA, homovanillic acid; 5-HT,...
Background and purpose: Pharmacological validation of novel functions for the a 2A -, a 2B -, and a 2C -adrenoceptor (AR) subtypes has been hampered by the limited specificity and subtype-selectivity of available ligands. The current study describes a novel highly selective a 2C -adrenoceptor antagonist, JP-1302 (acridin-9-yl-[4-(4-methylpiperazin-1-yl)-phenyl]amine). Experimental approach: Standard in vitro binding and antagonism assays were employed to demonstrate the a 2C -AR specificity of JP-1302. In addition, JP-1302 was tested in the forced swimming test (FST) and the prepulse-inhibition of startle reflex (PPI) model because mice with genetically altered a 2C -adrenoceptors have previously been shown to exhibit different reactivity in these tests when compared to wild-type controls. Key results: JP-1302 displayed antagonism potencies (K B values) of 1,500, 2,200 and 16 nM at the human a 2A -, a 2B -, and a 2C -adrenoceptor subtypes, respectively. JP-1302 produced antidepressant and antipsychotic-like effects, i.e. it effectively reduced immobility in the FST and reversed the phencyclidine-induced PPI deficit. Unlike the a 2 -subtype non-selective antagonist atipamezole, JP-1302 was not able to antagonize a 2 -agonist-induced sedation (measured as inhibition of spontaneous locomotor activity), hypothermia, a 2 -agonist-induced mydriasis or inhibition of vas deferens contractions, effects that have been generally attributed to the a 2A -adrenoceptor subtype. In contrast to JP-1302, atipamezole did not antagonize the PCPinduced prepulse-inhibition deficit. Conclusions and implications:The results provide further support for the hypothesis that specific antagonism of the a 2C -adrenoceptor may have therapeutic potential as a novel mechanism for the treatment of neuropsychiatric disorders.
The present data demonstrate that dexmedetomidine effectively prevents delayed neuronal death in CA3 area and in the dentate hilus in gerbil hippocampus when the management is started before the onset of ischemia and continued for 48 h after reperfusion. Inhibition of ischemia-induced norepinephrine release may be associated with neuroprotection by dexmedetomidine.
Atipamezole is an alpha2-adrenoceptor antagonist with an imidazole structure. Receptor binding studies indicate that its affinity for alpha2-adrenoceptors and its alpha2/alpha1 selectivity ratio are considerably higher than those of yohimbine, the prototype alpha2-adrenoceptor antagonist. Atipamezole is not selective for subtypes of alpha2-adrenoceptors. Unlike many other alpha2-adrenoceptor antagonists, it has negligible affinity for 5-HT1A and I2 binding sites. Atipamezole is rapidly absorbed and distributed from the periphery to the central nervous system. In humans, atipamezole at doses up to 30 mg/subject produced no cardiovascular or subjective side effects, while at a high dose (100 mg/subject) it produced subjective symptoms, such as motor restlessness, and an increase in blood pressure. Atipamezole rapidly reverses sedation/anesthesia induced by alpha2-adrenoceptor agonists. Due to this property, atipamezole is commonly used by veterinarians to awaken animals from sedation/anesthesia induced by alpha2-adrenoceptor agonists alone or in combination with various anesthetics. Atipamezole increased sexual activity in rats and monkeys. In animals with sustained nociception, atipamezole increased pain-related responses by blocking the noradrenergic feedback inhibition of pain. In tests assessing cognitive functions, atipamezole at low doses has beneficial effects on alertness, selective attention, planning, learning, and recall in experimental animals, but not necessarily on short-term working memory. At higher doses atipamezole impaired performance in tests of cognitive functions, probably due to noradrenergic overactivity. Recent experimental animal studies suggest that atipamezole might have beneficial effects in the recovery from brain damage and might potentiate the anti-Parkinsonian effects of dopaminergic drugs. In phase I studies atipamezole has been well tolerated by human subjects.
In the present study we evaluated the alpha 1- and alpha 2-adrenoceptor subtype binding, central alpha 2-adrenoceptor antagonist potency, as well as effects on brain neurochemistry and behavioural pharmacology of two alpha 2-adrenoceptor antagonists, atipamezole and yohimbine. Atipamezole had higher selectivity for alpha 2- vs. alpha 1-adrenoceptors than yohimbine regardless of the subtypes studied. Both compounds had comparable affinity for the alpha 2A-, alpha 2C- and alpha 2B-adrenoceptors, but yohimbine had significantly lower affinity for the alpha 2D-subtype. This may account for the fact that significantly higher doses of yohimbine than atipamezole were needed for reversal of alpha 2-agonist (medetomidine)-induced effects in rats (mydriasis) and mice (sedation and hypothermia). The effect on central monoaminergic activity was estimated by measuring the concentrations of transmitters and their main metabolites in whole brain homogenate. At equally effective alpha 2-antagonising doses in the rat mydriasis model, both drugs stimulated central noradrenaline turnover (as reflected by increase in metabolite levels) to the same extent. Atipamezole increased dopaminergic activity only slightly, whereas yohimbine elevated central dopamine but decreased central 5-hydroxytryptamine turnover rates. In behavioural tests, atipamezole (0.1-10 mg/kg) did not affect motor activity but stimulated food rewarded operant (FR-10) responding (0.03-3 mg/kg) whereas yohimbine both stimulated (1 mg/kg) and decreased (> or = 3 mg/kg) behaviour in a narrow dose range in these tests. In the staircase test, both antagonists increased neophobia, but in the two compartment test only yohimbine (> or = 3 mg/kg) decreased exploratory behaviour. The dissimilar effects of the antagonists on neurochemistry and behaviour are thought to be caused by non alpha 2-adrenoceptor properties of yohimbine. In conclusion, the alpha 2-antagonist atipamezole blocked all alpha 2-adrenoceptor subtypes at low doses, stimulated central noradrenergic activity and had only slight effects on behaviour under familiar conditions, but increased neophobia. The low affinity for the alpha 2D-adrenoceptor combined with its unspecific effects complicates the use of yohimbine as pharmacological tool to study alpha 2-adrenoceptor physiology and pharmacology.
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