Raymond G. Booth

(+)-6,7-Benzomorphan sigma ligands stimulate dopamine synthesis in rat corpus striatum tissue

The benzomorphan sigma ligands, (+)-N-allylnormetazocine (NANM) and (+)-pentazocine, but not (+)-cyclazocine, stereospecifically stimulated dopamine synthesis in minces of rat corpus striatum by 15-23% over basal values at 0.1-1.0 microM. The effect of (+)-NANM and (+)-pentazocine was blocked by the reported sigma antagonist, BMY-14802 but not by the opiate antagonist naloxone. These results suggest that these (+)-benzomorphans may act as agonists at putative sigma heteroreceptors on striatal nerve terminals, or through an indirect mechanism, to modulate dopamine synthesis.

Dopamine D1 autoreceptor function: possible expression in developing rat prefrontal cortex and striatum

Synthesis-modulating dopamine (DA) autoreceptor function was studied in vivo using gamma-butyrolactone (GBL) to block propagation along DA axons. DA synthesis was measured by the accumulation of L-3,4-dihydroxyphenylalanine (L-DOPA) after inhibition of aromatic L-amino acid decarboxylase. GBL treatment markedly increased DOPA accumulation in both the striatum and prefrontal cortex of developing rats. The selective DA partial D1 agonist SKF-38393 inhibited this GBL-induced rise in DA synthesis in both the striatum and prefrontal cortex of 15- and 22-day-old rats, but not in adults. The effects of SKF-38393 in developing rats were mimicked by the non-catechol D1 partial agonist CY-208-243, and were blocked by the D1 antagonist SCH-23390, suggesting receptor mediation. The mixed D2/D3 agonist quinpirole attenuated DA synthesis in striatum of both two-week-old and adult rats, but failed to inhibit the GBL-induced increase in DA synthesis in the developing prefrontal cortex. These findings suggest that synthesis-modulating D1-like receptor function may emerge transiently in the developing mammalian forebrain. In the adult striatum these functions appear to be subsumed by D2-like receptors, whereas all synthesis-modulating DA receptor function in prefrontal cortex appears to be essentially lost with maturation.

GPCR proteomics: mass spectrometric and functional analysis of histamine H1 receptor after baculovirus-driven and in vitro cell free expression

The human histamine H1 Receptor (hH1R) belongs to the family of G-protein coupled receptors (GPCRs), an attractive and proven class of drug targets in a wide range of therapeutic areas. However, due to the low amount of available purified protein and the hydrophobic nature of GPCRs, limited structural information is available on ligand-receptor interaction especially for the transmembrane (TM) domain regions where the majority of ligand-receptor interactions occur. During the last decades, proteomic techniques have increasingly become an important tool to reveal detailed information on the individual GPCR class, including post-translational modifications and characterizations of GPCRs binding pocket. Herein, we report the successful functional production and mass spectrometric characterization of the hH1R, after baculovirus-driven and in vitro cell-free expression. Using only MALDI-ToF, sequence coverage of more than 80%, including five hydrophobic TM domains was achieved. Moreover, we have identified an asparagine residue in the hH1R protein that is subject to N-linked glycosylation. This information would be valuable for drug discovery efforts by allowing us to further study H1R-ligand interactions using histaminergic ligands that covalently bind the hH1R, and eventually revealing binding sites of hH1R and other GPCRs.

Actions of (±)-7-hydroxy-N,N-dipropylaminotetralin (7-OH-DPAT) on dopamine synthesis in limbic and extrapyramidal regions of rat brain

The proposed D3-selective ligand (+/-)-7-hydroxy-N,N-dipropylaminotetralin (7-OH-DPAT) inhibited tyrosine hydroxylase in vitro (IC50 = 0.6-0.7 microM) and dihydroxyphenylalanine (DOPA) accumulation in vivo (ID50 = 4.8-6.4 mg/kg) in two autoreceptor models in extrapyramidal and limbic tissue in rat forebrain, without consistent regional selectivity. Some limbic selectivity (ID50 = 10 vs. 29 mg/kg) was found in an in vivo model permitting expression of postsynaptic D3 and D2 receptor activity. The effects were partially blocked by S(-)-eticlopride alone, and fully after reserpine pretreatment. The results suggest that 7-OH-DPAT activates D3 or D2 autoreceptors, alters dopamine storage or release, and may interact with some limbic selectivity at postsynaptic D3 and D2 receptors as a partial agonist.

Putative σ3 sites in mammalian brain have histamine H1 receptor properties: evidence from ligand binding and distribution studies with the novel H1 radioligand [3H]-(−)-trans-1-phenyl-3-aminotetralin

A novel phenylaminotetralin (PAT) radioligand, [(3)H]-(1R, 3S)-(-)-trans-1-phenyl-3-dimethylamino-1,2,3,4-tetrahydronaphthalene ([(3)H]-[-]-trans-H(2)-PAT), is shown here to label a saturable (B(max)=39+/-6 fmol/mg protein) population of sites with high affinity (K(d)=0.13+/-0.03 nM) in guinea pig brain. Consistent with previous studies which showed that PATs stimulate catecholamine (dopamine) synthesis in rat striatum, autoradiographic brain receptor mapping studies here indicate that [(3)H]-(-)-trans-H(2)-PAT-labeled sites are highly localized in catecholaminergic nerve terminal fields in hippocampus, nucleus accumbens, and striatum in guinea pig brain. Competition binding studies with a broad range of CNS receptor-active ligands and CNS radioreceptor screening assays indicate that the pharmacological binding profile of brain [(3)H]-(-)-trans-H(2)-PAT sites closely resembles histamine H(1)-type receptors. Comparative studies using the histamine H(1) antagonist radioligand, [(3)H]mepyramine, indicate that the H(1) ligand binding profile and guinea pig brain distribution of H(1) receptors and [(3)H]-(-)-trans-H(2)-PAT sites are nearly identical; moreover, both sites have about 40-fold stereoselective affinity for (-)- over (+)-trans-H(2)-PAT. These results are discussed in light of previous studies which suggested that PATs stimulate dopamine synthesis through interaction with a novel sigma-type (sigma(3)) receptor in rodent brain; it now appears instead that PATs represent a new class of ligands for brain histamine H(1) receptors that can be stereoselectively labeled with [(3)H]-(-)-trans-H(2)-PAT.

A novel phenylaminotetralin (PAT) recognizes histamine H1 receptors and stimulates dopamine synthesis in vivo in rat brain

A series of novel phenylaminotetralins (PATs) previously was shown to recognize discrete binding sites that are stereoselectively labeled by [3H]-(-)-trans-1-phenyl-3-N,N-dimethylamino-1,2,3,4-tetrahydronaphthalen e (H2-PAT) and highly localized in catecholaminergic nerve terminal regions in guinea pig forebrain. Furthermore, certain PATs stimulate tyrosine hydroxylase and dopamine synthesis in guinea pig and rat brain in vitro. In the current studies, we characterized sites labeled by [3H]-(-)-trans-H2-PAT and measured effects of PATs on dopamine synthesis in vivo in rat brain. [3H]-(-)-Trans-H2-PAT binds saturably (Bmax approximately 13 fmol/mg protein) and with high affinity (K(D) approximately 0.5 nM) to a single population of sites in rat brain. The ligand binding profile of [3H]-(-)-trans-H2-PAT labeled sites is very similar to histamine H1 receptors labeled with [3H]-mepyramine. After i.c.v. injection to rats, (+/-)-trans H2-PAT (4-40 nmoles/kg) stimulates dopamine synthesis (to about 180% of control levels) selectively in the limbic brain region nucleus accumbens vs. the extrapyramidal region striatum; this effect is fully blocked by (+/-)-cis-H2-PAT and the H1 antagonist triprolidine. At higher doses (> 40 nmoles/kg), the observed stimulation of dopamine synthesis is attenuated to control levels, likely due to activation of feedback mechanisms resulting from non-receptor mediated displacement of intraneuronal dopamine. We propose that PATs represent a novel class of ligands for H1 receptors that can modulate tyrosine hydroxylase activity and dopamine synthesis in the limbic region of mammalian forebrain.

Adenosine A2 stimulation of tyrosine hydroxylase in rat striatal minces is reversed by dopamine D2 autoreceptor activation

The adenosine agonist, 2-chloroadenosine, stimulated tyrosine hydroxylase activity in rat striatal minces; this effect was attenuated by activation of dopamine (DA) D2 autoreceptors with N-n-propylnorapomorphine and antagonized by theophylline. Forskolin and 8-bromo-cAMP also increased tyrosine hydroxylase activity and their effects were not altered by 2-chloroadenosine. D1, alpha, beta and 5-HT agonists did not affect tyrosine hydroxylase activity. Evidently, A2 receptors on DA nerve terminals stimulate striatal DA synthesis and this effect is negatively modulated by D2 autoreceptors, probably via changes in intracellular cAMP levels.

2-Phenylaminoadenosine stimulates dopamine synthesis in rat forebrain in vitro and in vivo via adenosine A2 receptors

The adenosine agonist 2-phenylaminoadenosine (PAD) stimulated tyrosine hydroxylase activity in rat striatum in vitro. This effect was selectively blocked by the A2 antagonist 8-chlorostyrylcaffeine (CSC), suggesting an A2 receptor-mediated mechanism. PAD also produced a corresponding increase in striatal adenylyl cyclase activity. Using an in vivo model that measures presynaptic effects of drugs at dopamine nerve terminals, intracerebroventricular administration of PAD to rats stimulated tyrosine hydroxylase activity in striatum in a manner that was selectively blocked by CSC. These results suggest that PAD stimulates adenylyl cyclase and tyrosine hydroxylase activity, with a corresponding increase in dopamine synthesis, by activation of presynaptic A2-type receptors in mammalian forebrain.

Inhibition of dopamine synthesis in rat striatal minces: evidence of dopamine autoreceptor supersensitivity to S(+)- but not R(-)-N-n-propylnorapomorphine after pretreatment with fluphenazine.

This study provides in vitro evidence that rats pretreated with fluphenazine for 10 days, but not acutely, developed moderate but significant striatal autoreceptor supersensitivity as measured by the ability of S(+)-NPA, a selective DA autoreceptor agonist and very weak postsynaptic agonist, to inhibit tyrosine hydroxylase activity. In contrast, autoreceptor supersensitivity was not found with the nonselective auto- and postsynaptic receptor agonist R(-)-NPA. Presumably, this effect represents some modification of a presynaptic regulatory mechanism controlling DA synthesis which can occur despite a reportedly high striatal DA autoreceptor reserve in rat striatum [2, 7]. Such a mechanism, by tending to reduce synaptic availability of DA, may contribute to tolerance to the transient, early DA-synthesis stimulating actions of acutely administered neuroleptics [4], and help to counterbalance increases in postsynaptic DA receptor abundance and sensitivity associated with long-term neuroleptic treatment.