Synthesis and biological evaluation of a series of novel N- or O-fluoroalkyl derivatives of tropane: potential positron emission tomography (PET) imaging agents for the dopamine transporter.

A series of novel fluoroalkyl-containing tropane derivatives was synthesized, and their binding affinities for the dopamine transporter (DAT), serotonin transporter (SERT), and norepinephrine transporter (NET) were determined via competitive binding assays. Among these derivatives, the fluoropropyl ester of beta-CIT (19), the fluoroethyl ester of beta-CIT (20), the N-fluoropropyl derivative of beta-CBT (12), and the fluoropropyl ester of beta-CMT (18) displayed higher affinity and greater selectivity for the DAT versus SERT and NET than FP-CIT, which indicates that they are attractive candidates for the development of (18)F-labeled PET imaging agents for the DAT.

Fatty acid derivatives of clozapine: prolonged antidopaminergic activity of docosahexaenoylclozapine in the rat.

Stable amides of clozapine derived from fatty acids prominent in cerebral tissue might enhance the central activity of clozapine and reduce its exposure to peripheral tissues. Such derivatives might enhance the safety of this unique drug, which is the only agent with securely established superior antipsychotic effectiveness, but with a risk of potentially lethal systemic toxicity. Amide derivatives of clozapine were prepared from structurally varied fatty acid chlorides and evaluated for ability to inhibit behavioral arousal in rat induced by dopamine agonist apomorphine and to induce catalepsy. Their duration-of-action and potency were compared to free clozapine, and concentrations of clozapine were assayed in brain and blood. Selected agents were also evaluated for affinity at dopamine receptors and other potential drug-target sites. Clozapine-N-amides of linoleic, myristic, oleic, and palmitic acids had moderate initial central depressant activity but by 6 h, failed to inhibit arousal induced by apomorphine. However, the docosahexaenoic acid (DHA) derivative was orally bioavailable, 10-times more potent (ED(50) 5.0 micromol/kg) than clozapine itself, and very long-acting (>/= 24 h) against apomorphine, and did not induce catalepsy. DHA itself was inactive behaviorally. Clozapine showed expected dopamine receptor affinities, but DHA-clozapine was inactive at these and other potential target sites. After systemic administration of DHA-clozapine, serum levels of free clozapine were very low, and brain concentrations somewhat lower than after administering clozapine. DHA-clozapine is a long-acting central depressant with powerful and prolonged antidopaminergic activity after oral administration or injection without inducing catalepsy, and it markedly reduced peripheral exposure to free clozapine. It lacked the receptor-affinities shown by clozapine, suggesting that DHA-clozapine may be a precursor of free, pharmacologically active clozapine. Such agents may represent potential antipsychotic drugs with improved central/peripheral distribution, and possibly enhanced safety.

Synthesis and monoamine transporter affinity of 2beta-carbomethoxy-3beta-(2''-, 3''- or 4''-substituted) biphenyltropanes.

A series of 11 novel 3beta-substituted biphenyltropanes was synthesized and evaluated by selective radioligand binding assays for affinity to monoamine transporters. Both 5-HTT potency and selectivity for 5-HTT over DAT was greatest with electron withdrawing group at the 3''-position.

Alkylation of rat dopamine transporters and blockade of dopamine uptake by EEDQ.

Effects of the alkylating agent EEDQ (N-ethoxycarbonyl-2-ethoxy-1, 2-dihydroquinoline) on levels of dopamine transporter (DA(T)) and function were examined in caudate-putamen (CPu) tissue from rat brain. EEDQ produced profound, dose-dependent decreases in DA(T) binding in homogenates (IC(50)=78 microM) and frozen sections (IC(75)=200 microM) that were not reversed by washing. EEDQ also blocked uptake of [(3)H]DA in CPu synaptosomes (IC(50)=17 microM). However, single (10 mg/kg) or repeated administration of EEDQ in vivo (15 mg/kg/day x 3) did not alter DA(T) levels or DA uptake in CPu. Pretreatment of rats with alpha-methyl-p-tyrosine and reserpine to deplete endogenous dopamine also failed to lower DA(T) levels in CPu after injections of EEDQ. EEDQ is an effective alkylating agent for DA(T) in vitro, but not to evaluate metabolic turnover or function of DA(T) in vivo. The results encourage development of selective and in vivo-active DA(T)-alkylating agents.

Cyclopentadienyltricarbonylrheniumbenzazepines: synthesis and binding affinity.

Analogues of the benzazepine dopamine D1 receptor antagonist SCH-23390 incorporating the cyclo-pentadienyltricarbonyl-rhenium (CPTR) moiety were synthesized and evaluated pharmacologically. The CPTR derivatives retained affinity (0.3-2.9 nM) and D1 selectivity of the parent compound, supporting their use as neuropharmacological surrogates for 99mTc-labeled SPECT radiopharmaceuticals.

[3H]beta-CIT: a radioligand for dopamine transporters in rat brain tissue.

[3H]2-beta-carbomethoxy-3-beta-[4'-iodophenyl]tropane (beta-CIT) was prepared and evaluated. With rat forebrain tissue, [3H]beta-CIT showed high affinity for dopamine transporters (DAT), with selectivity for DAT over norepinephrine transporters, but not serotonin transporters, as well as DAT-stereoselectivity with beta-CIT, amphetamine and methylphenidate. Affinity and selectivity for 53 compounds assayed with [3H]beta-CIT and standard DAT radioligand [3H]GBR-12935 were highly correlated (r0.95). [3H]beta-CIT is proposed as a useful, high-affinity DAT radioprobe.

Selective alkylatation of dopamine D2 and D4 receptors in rat brain by N-(p-isothiocyanatophenethyl)spiperone.

Effects of the D2-like receptor alkylating agent NIPS (N-[p-isothiocyanatophenethyl]spiperone) on dopamine receptors in rat brain were characterized by radioreceptor assays and quantitative autoradiography. NIPS alkylated D2 and D4 receptors concentration-dependently in brain sections and transfected cells. NIPS also alkylated both receptors dose-dependently in vivo, with no effect on dopamine D1-like or serotonin 5-HT2 receptors at a dose that occluded 75% of D2 and D4 receptors. Pretreatment with D2-like receptor selective antagonist haloperidol completely blocked the effects of NIPS. The findings demonstrate that NIPS selectively alkylates D2 and D4 receptors, indicating its potential utility for studies of these receptors.

Effects of alkylating agents on dopamine D(3) receptors in rat brain: selective protection by dopamine.

Dopamine D(3) receptors are structurally highly homologous to other D(2)-like dopamine receptors, but differ from them pharmacologically. D(3) receptors are notably resistant to alkylation by 1-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ), which readily alkylates D(2) receptors. We compared EEDQ with N-(p-isothiocyanatophenethyl)spiperone (NIPS), a selective D(2)-like receptor alkylating agent, for effects on D(3) and D(2) receptors in rat brain using autoradiographic analysis. Neither agent occluded D(3) receptors in vivo at doses that produced substantial blockade of D(2) receptors, even after catecholamine-depleting pretreatments. In vitro, however, D(3) receptors were readily alkylated by both NIPS (IC(50)=40 nM) and EEDQ (IC(50)=12 microM). These effects on D(3) sites were blocked by nM concentrations of dopamine, whereas microM concentrations were required to protect D(2) receptors from the alkylating agents. The findings are consistent with the view that alkylation of D(3) receptors in vivo is prevented by its high affinity for even minor concentrations of endogenous dopamine.

Neuropharmacological assessment of potential dopamine D4 receptor-selective radioligands.

Radiolabeled dopamine D4 receptor-selective agents ([3H]1-benzyl-4-[ N-(3-isopropoxy-2-pyridinyl)-N-methyl]-aminopiperidine maleate; [3 H]PNU-101958. and [125I]1-[4-iodobenzyl]-4-[ N-(3-isopropoxy-2-pyridinyl)-N-methyl]-aminopiperidine; [125I]RBI-257) were prepared and characterized. With D4.2- and D2L receptor-transfected cell membranes, [3H]PNU-101958 showed high dopamine D4 receptor affinity and selectivity, and potent inhibition by dopamine D4 receptor-selective compounds. However, its binding with rat brain homogenates showed little regional selectivity, and pharmacology inconsistent with selective dopamine D4 receptor labeling. Autoradiography indicated partial displacement of [3H]PNU-101958 by unlabeled dopamine D4 receptor ligands without regional selectivity, and lack of selective labeling with [125I]RBI-257. The results encourage further efforts to develop better dopamine D4 receptor-selective radioligands.

Local injection of alkylating and nonalkylating dopamine receptor antagonists into rat basal forebrain: autoradiographic assessment of D2-like and D3 sites.

N-chloroethyl derivatives of 7-hydroxy-1,2,3,4-tetrahydronaphthalene (7-OH-DPAT), 1-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ), or fluphenazine were microinjected into rat nucleus accumbens (Acc), and receptor binding quantified autoradiographically after 24 h. EEDQ reduced [3H]nemonapride (D2-like receptors) binding in Acc (by 84%) and islands of Calleja (IC; 44%), without affecting [3H](+)-7-OH-DPAT (D3); N-chloroethyl-7-OH-DPATs blocked both radioligands in Acc and IC (30%-70%); fluphenazine had no effect.

Long-term effects of S(+)N-n-propylnorapomorphine compared with typical and atypical antipsychotics: differential increases of cerebrocortical D2-like and striatolimbic D4-like dopamine receptors.

Changes in D2-like dopamine (DA) receptor binding in rat brain regions were compared by quantitative in vitro receptor autoradiography after 21-d treatment with a typical (fluphenazine), atypical (clozapine), or candidate atypical antipsychotic (S[+]-N-n-propylnorapomorphine, [+]-NPA). Fluphenazine treatment significantly increased binding of the D2,3,4 radioligands [3H]nemonapride and [3H]spiperone in caudate-putamen (CPu: 22%, 32%), nucleus accumbens (ACC: 67%, 52%), olfactory tubercle (OT: 53%, 43%), and medial prefrontal cerebral cortex (MPC: 46%, 47%) but not dorsolateral frontal cortex (DFC). D2-like binding in MPC was also increased by (+)-NPA (49%, 39%) and clozapine (60%, 40%), but not in DFC, CPu, ACC, or OT. Binding of D2,3-selective [3H]raclopride increased less after fluphenazine in ACC (27%) and CPu (16%) than with the nonselective radioligands, and not after clozapine or (+)-NPA. D3-selective binding of [3H]R (+)-7-OH-DPAT was not changed with any treatment or region including islands of Calleja. Binding of [3H]nemonapride or [3H]spiperone under D4-selective conditions (with 300 nM S[-]-raclopride and other masking agents, at sites occluded by D4 ligand L-745,870), was increased by fluphenazine, (+)-NPA, clozapine in ACC (120%, 76%, 70%, respectively), and CPu (54%, 37%, 35%), but not in OT, DFC or MPC. These results support the hypothesis that cerebrocortical D2-like and striatolimbic D4-like receptors contribute to antipsychotic actions of both typical and atypical drugs and encourage further consideration of S(+)aporphines as potential atypical antipsychotics.

RBI-257: a highly potent dopamine D4 receptor-selective ligand.

RBI-257 (1-[4-iodobenzyl]-4-[N-(3-isopropoxy-2-pyridinyl)-N-methyl]-aminopiperid ine), the p-iodobenzyl analog of U-101,958 (1-benzyl-4-[N-(3-isopropoxy-2-pyridinyl)-N-methyl]-aminopiperidine) had a lower dissociation constant (Ki = 0.3 vs. 2.7 nM) and higher selectivity than U-101,958 at dopamine D4 receptors, over dopamine D2 and D3 receptors in transfected cell membranes and D2-like sites in rat forebrain. Dopamine D4 receptor affinity of iodo-isomers of RBI-257 ranked: para > meta > ortho. RBI-257 had much lower affinity at D1 and D5 dopamine receptors in transfected cells, as well as dopamine D1-like receptors, alpha1, alpha2 or beta(1,2) adrenoceptors, sigma(1,2) receptors and 5-HT1A or 5-HT2A receptors, and transporters for dopamine, norepinephrine or serotonin in rat forebrain tissue. RBI-257 may be a useful probe or radioligand for brain dopamine D4 receptors.

Role of dopamine in behavioral effects of serotonin microinjected into rat striatum.

Bilateral local microinfusion of serotonin (5-hydroxytryptamine; 5-HT) into the ventrolateral striatum (VLS) of the rat forebrain induces quantifiable stereotyped orofacial behaviors. The role of presynaptic dopamine (DA) and structural requirements of indoles for expression of this behavioral effect and for inhibition of neuronal transport of [3H]DA were examined. Bilateral local injection of 6-OHDA (8 micrograms/side) into VLS depleted DA and markedly diminished the behavioral effects of 5-HT. Intracerebral pretreatment with the potent DA transport inhibitors GBR-12909 (6 micrograms/side) or nomifensine (4 micrograms/side) also markedly decreased behavioral responses to 5-HT. A series of indoles and tyramine were examined for ability to induce stereotypy following infusion into the VLS. Of compounds tested, only p-tyramine, 5-HT, tryptamine and L-5-hydroxytryptophan (5-HTP) elicited strong orofacial behaviors; indoles lacking a free amino group or containing other substituents were virtually inactive in vivo, and the effect of 5-HTP was prevented by systemic pretreatment with the decarboxylase inhibitor NSD-1015, indicating its required conversion to 5-HT. Uptake of [3H]DA (0.1 microM) into rat striatal synaptosomes was inhibited in a concentration-dependent manner in the following apparent rank-order: p-tyramine, N-methyl-5-HT, tryptamine, 5-HT, N-methyltryptamine (IC50 = 44-718 nM), other indoles (IC50 = 10-100 microM). These results support the conclusion that oral stereotypy induced by microinjection of 5-HT or other aromatic amines into rat VLS is mediated by local release of endogenous DA. These results extend previous findings indicating that this effect of 5-HT was not blocked by 5-HT receptor antagonists, and suggest mediation by a neuronal transport process involved in the uptake or storage of DA.

Regional distribution of dopamine D4 receptors in rat forebrain.

Binding of the D2-like (D2/D3/D4) radioligand [3H]nemonapride under selective conditions (with 300 nM S[-]-raclopride and other masking agents to occlude D2/D3 receptors and non-specific binding sites) revealed a subset of raclopride-insensitive binding sites considered D4-like receptors. These sites were stereoselective to R(-)-N-n-propylnorapomorphine (NPA) over its S(+)-NPA in a similar fashion to cloned D4 receptors expressed in cell lines. In addition, the highly D4-selective agent L-745,870 displaced 74-83% of these sites in rat brain regions, suggesting that most were D4 receptors. These apparent D4 receptors represented a relatively high proportion of D2-like receptors in hippocampus, dorsolateral frontal, medial prefrontal and entorhinal cortex, but fewer in caudate-putamen and nucleus accumbens.

N-substituted analogs of 2 beta-carbomethoxy-3 beta- (4'-iodophenyl)tropane (beta-CIT) with selective affinity to dopamine or serotonin transporters in rat forebrain.

This report concerns the synthesis and chemical characterization of novel series of N-substituted 2 beta-carbomethoxy-3 beta-(4'-iodophenyl)tropane (beta-CIT, 2) analogs and their neuropharmacological evaluation for affinity at dopamine (DAT), serotonin (5-HTT), and norepinephrine membrane transporters in rat brain tissue. N-Substituted analogs of beta-CIT with a 2 beta-carbomethoxy ester moiety showed lower DAT affinity than beta-CIT for the DAT, and some were more selective for the 5-HTT over the DAT. 2 beta-Carbomethoxy(iodophenyl)nortropane analogs of beta-CIT with the N-substituents difluoroethyl, mesoxypropyl, iodopropyl, and methylpropionyl all yielded > 10-fold lower DAT affinity than beta-CIT itself, whereas the N-(fluoropropyl)-2 beta- isopropyl ester analog (1) of beta-CIT exceeded beta-CIT (2, an N-methyl-2 beta-carbomethoxy ester) in DAT affinity. Several N-haloalkyl-substituted beta-CIT analogs yielded high 5-HTT affinity (Ki < 0.6 nM), ranking: N-fluoropropyl (5) > N-chloropropyl (4) > or = N-bromopropyl (3) > beta-CIT (2) > N-3'-phtalimidopropyl (11), with particularly high (ca. 30-fold) 5-HTT-over-DAT selectivity found in the N-fluoropropyl (5) and N-fluoroethyl (6) compounds, compared to only 3.o-fold 5-HTT selectivity in beta-CIT itself. Highly 5-HTT selective agents such as 5 and 6 may be useful as brain-imaging ligands for serotonin neurons or as mood-elevating drugs, while the high affinity and selectivity for the DA transporter found in N-(fluoropropyl)-2 beta-(carboxyisopropyl)-3 beta-(4'-iodophenyl)-nortropane (1) and N-(fluoropropyl)-2 beta-carboxymethoxy-3 bet-(4'-iodophenyl)nortropane (FP-beta-CIT, 5) support their use as improved markers for DA neurons.

Distribution of fluphenazine and its metabolites in brain regions and other tissues of the rat.

Rats were given 5, 10, or 20 mg/kg oral doses of fluphenazine (FLU) dihydrochloride daily for 15 days. FLU and its sulfoxide (FL-SO), 7-hydroxy (7-OH-FLU) and N4'-oxide (FLU-NO) metabolites were assayed in plasma, liver, kidney, fat, whole brain, and brain regions by specific and sensitive radioimmunoassays (RIA). All metabolites were detected in tissues at higher levels than in plasma, and the levels increased with dose. FLU was 10- to 27-fold higher in brain regions than in plasma. Brain vs plasma levels of FLU correlated more closely than levels of its metabolites. Liver contained the highest levels of all analytes at all doses. FLU-SO was the major metabolite in brain regions (24% to 96% of FLU) and accumulated in fat 43 to 75 times more than FLU. Levels of 7-OH-FLU and FLU-NO were very low in brain (1% to 20% of FLU). FLU-SO and FLU-NO had only 1% to 3% the affinity for D1 and D2 receptors, but 7-OH-FLU had 20% the D2 and 5% the D1 affinity of FLU. The low affinity for dopamine receptors and low brain-levels of metabolites of FLU indicate that they are not likely to contribute importantly to pharmacologic responses of FLU. Also, the estimated relative "activity factor" for these compounds in the brain indicated that the contribution to neuropharmacologic activity by metabolites is less than 1% of FLU. Consequently, clinical monitoring of plasma FLU alone may be sufficient.

1-Phenyl-3-amino-1,2,3,4-tetrahydronaphthalenes and related derivatives as ligands for the neuromodulatory sigma 3 receptor: further structure-activity relationships.

A series of 1-phenyl-3-amino-1,2,3,4-tetrahydronaphthalenes (1-phenyl-3-aminotetralins, PATs) previously was found to stimulate tyrosine hydroxylase activity and dopamine synthesis in rat brain through interaction with a novel sigma 3 receptor. Specifically, the trans-1R,3S-(-) isomer of H2-PAT showed highest affinity for sigma 3 receptors and also produced maximal stimulation of tyrosine hydroxylase activity and dopamine synthesis, as compared to the trans-1S,3R-(+) isomer. Affinity for sigma 3 receptors and functional potency at stimulating dopamine synthesis were attenuated either by altering the position or dimethyl substitution pattern of the amino group or by hydroxylating the tetralin aromatic ring. A preliminary binding model can accommodate many PAT analogs and several non-PATs with a wide range of affinities for the sigma 3 receptor. Here, we report the synthesis and evaluation of additional analogs in order to expand previous structure-activity relationship studies. Further molecular modifications include synthesis of 1-phenyl-1-methyl-3-amino, 1-phenyl-2-amino, 1-phenyl-3-(trimethylammoniumyl), and 1-phenyl-3-(phenylalkyl) analogs, as well as ring-expanded tetrahydrobenzocycloheptenes. In general, the above modifications decreased sigma 3 receptor affinity and, in some cases, caused a reversal of the sigma 3 binding selectivity of trans- versus cis-PATs found previously. Most analogs were selective for sigma 3 receptors and showed little or no affinity for either sigma 1/sigma 2 or dopamine D1, D2, and D3 receptors. N-Phenylalkyl substituents, such as N-phenylethyl, however, endowed the 1-phenyl-3-aminotetralins with enhanced sigma 1/sigma 2 and dopamine receptor affinity while decreasing sigma 3 affinity, thus abolishing sigma 3 selectivity.

Conformational analysis, pharmacophore identification, and comparative molecular field analysis of ligands for the neuromodulatory sigma 3 receptor.

Molecular modeling studies were carried out on a series of 1-phenyl-3-amino-1,2,3,4-tetrahydronaphthalenes (phenylaminotetralins, PATs), several PAT structural analogs, and various non-PAT ligands that demonstrate a range of affinities for a novel sigma 3 receptor linked to stimulation of tyrosine hydroxylase and dopamine synthesis in rodent brain. In an effort to develop a ligand-binding model for the sigma 3 receptor, a pharmacophore mapping program (DISCO) was used to identify structural features that are common to ligands that exhibit moderate to high binding affinity for sigma 3 sites. DISCO then was utilized to propose a common pharmacophoric region that included one low-energy conformation of each compound in the training set. The resulting alignment was utilized in a comparative molecular field analysis (CoMFA) study in an attempt to correlate the steric and electrostatic fields of the molecules with the respective binding affinities at the sigma 3 receptor. A suitably predictive model was obtained from the CoMFA analysis which will be employed in the development of additional PAT analogs that could potentially display high affinity and selectivity for the sigma 3 receptor. The excluded volumes which resulted from comparing molecular volumes of active and inactive compounds were visualized to examine the limits of steric tolerance imposed by the sigma 3 receptor.