High-content phenotypic screening identifies novel chemistries that disrupt mosquito activity and development.

New classes of chemistries are needed to control insecticide resistant populations of mosquitoes and prevent transmission of vector-borne diseases (VBDs). Organismal screens of chemical collections have played an important role in the search for new vector insecticides and the identification of active ingredients (AIs) that cause rapid mortality of mosquitoes. Advances in image-based screening offer an opportunity to identify chemistries that operate via novel biochemical modes and investigate the range of phenotypes exhibited by mosquitoes following exposure to lethal and sub-lethal chemical dose. An automated, high throughput phenotypic screen (HTS) employing high-content imaging of first instar (L1) Aedes aegypti larvae was developed to identify chemistries associated with mortality and atypical morphological phenotypes. A pilot screen of the Library of Pharmacologically Active Compounds (LOPAC1280) identified 92 chemistries that disrupted larval activity and development, including conventional insecticides and chemistries known to modulate G protein-coupled receptors (GPCRs) and other molecular targets in mammalian systems. Secondary assay series were used to evaluate a selection of chemistries for impacts on mosquito activity, survival and development. Ritodrine hydrochloride reduced mobility of larvae but had no observable effect on survival and development of mosquitoes. High doses of metergoline suppressed larval activity and sub-lethal dose resulted in pupal mortality. Assay data support the utility of phenotypic screening and diverse entomological end-points for discovery of novel insecticidal chemical scaffolds. The insecticide discovery process must consider how multi-modal efficacy spectra contribute to vector and VBD control.

Functional characterization of AC5 gain-of-function variants: Impact on the molecular basis of ADCY5-related dyskinesia.

Adenylyl cyclases are key points for the integration of stimulatory and inhibitory G protein-coupled receptor (GPCR) signals. Adenylyl cyclase type 5 (AC5) is highly expressed in striatal medium spiny neurons (MSNs), and is known to play an important role in mediating striatal dopaminergic signaling. Dopaminergic signaling from the D1 expressing MSNs of the direct pathway, as well as the D2 expressing MSNs of the indirect pathway both function through the regulation of AC5 activity, controlling the production of the 2nd messenger cAMP, and subsequently the downstream effectors. Here, we used a newly developed cell line that used Crispr-Cas9 to eliminate the predominant adenylyl cyclase isoforms to more accurately characterize a series of AC5 gain-of-function mutations which have been identified in ADCY5-related dyskinesias. Our results demonstrate that these AC5 mutants exhibit enhanced activity to Gαs-mediated stimulation in both cell and membrane-based assays. We further show that the increased cAMP response at the membrane effectively translates into increased downstream gene transcription in a neuronal model. Subsequent analysis of inhibitory pathways show that the AC5 mutants exhibit significantly reduced inhibition following D2 dopamine receptor activation. Finally, we demonstrate that an adenylyl cyclase "P-site" inhibitor, SQ22536 may represent an effective future therapeutic mechanism by preferentially inhibiting the overactive AC5 gain-of-function mutants.

Concentration of enzyme-dependent activation of PLC-beta 1 and PLC-beta 2 by G alpha 11 and beta gamma-subunits.

Differential regulation of PLC-beta 1 and -beta 2 by the G-protein alpha-subunit, G alpha 11, and by G-protein beta gamma-subunits was studied utilizing recombinant PLC-beta 1 and -beta 2. Rat PLC-beta 1 and human PLC-beta 2 were purified after recombinant baculovirus-mediated expression in Sf9 cells. The catalytic properties of the purified recombinant isoenzymes were directly compared to PLC-beta 1 purified from bovine brain and PLC-beta 2 partially purified from HL60 polymorphonuclear neutrophils. The recombinant isoenzymes were indistinguishable from the native isoenzymes with respect to dependence of reaction velocity on bulk PtdIns(4,5)P2 substrate concentration, pH, and free Ca2+ concentration. Marked AlF(4-)-dependent activation was observed upon reconstitution of rPLC-beta 1 with the G-protein alpha-subunit, G alpha 11. Activation occurred with a concentration dependence on G alpha 11 for activation and elevation in reaction velocity that was similar to that of native PLC-beta 1. In contrast, G alpha 11 promoted only a small elevation in the catalytic rate of recombinant PLC-beta 2, which was also typical of the native isoenzyme. Maximal reaction rates with respect to PLC-beta isoenzyme concentration were achieved and indicated that rPLC-beta 2 required 10-fold greater concentrations of both G alpha 11 and of rPLC-beta 2 for activation than did rPLC-beta 1. rPLC-beta 1 and rPLC-beta 2 were also differentially regulated by beta gamma-subunits. This differential activation was not the result of different concentration dependencies on beta gamma-subunit for activation, but rather, the result of the greater degree to which the catalytic rate of PLC-beta 2 was elevated by beta gamma-subunits when compared to PLC-beta 1.

Adrenergic agonists induce heterologous sensitization of adenylate cyclase in NS20Y-D(2L) cells.

Adenylate cyclase activity in NS20Y cells expressing D2L dopamine receptors was examined following chronic treatment with norepinephrine and epinephrine. Initial acute experiments revealed that both norepinephrine and epinephrine inhibited forskolin-stimulated cyclic AMP accumulation via D2 receptors. Furthermore, chronic 18 h activation of D2 dopamine receptors by norepinephrine or epinephrine induced a marked increase (>10-fold) in subsequent forskolin-stimulated cyclic AMP accumulation. This heterologous sensitization of adenylate cyclase activity was blocked by D2 dopamine receptor antagonists and by pertussis toxin pretreatment. In contrast, concurrent activation of Galpha(s) or adenylate cyclase did not appear to alter noradrenergic agonist-induced sensitization.

"Full" dopamine D1 agonists in human caudate: biochemical properties and therapeutic implications.

Recent data indicate that full D1 dopamine agonists have greater antiparkinsonian effects in the MPTP primate model than do partial agonists, suggesting that the intrinsic activity of D1 agonists may affect their utility in the treatment of Parkinson's disease. It is unclear, however, whether human D1 receptors in situ are similar to D1 receptors in other species or in molecular expression systems. For this reason, the binding affinity and functional activity of a series of D1 dopamine receptor agonists [dihydrexidine (DHX), SKF82958, and A68930] were determined in postmortem human caudate. Results from in vitro binding studies with membranes from human caudate indicate that these D1 agonists competed for [3H]SCH23390 labeled sites with a rank order similar to that found in rat striatum [K50 = 36.8 nM (DHX); 18.6 nM (SKF82958); 3.9 nM (A68930)]. The ability of these compounds and the partial agonist SKF38393 to stimulate the enzyme adenylyl cyclase in tissue homogenates of human caudate was also examined. DHX and A68930 are full agonists compared to dopamine, whereas SKF82958 and SKF38393 are partial agonists. These differences in biochemical intrinsic activity are consistent with the profound antiparkinsonian effects caused by DHX, but not by SKF82958 and SKF38393, in the MPTP-monkey model. This suggests that DHX and A68930 may be of greater utility in treating disorders where a full efficacy D1 agonist may be required.

Further definition of the D1 dopamine receptor pharmacophore: synthesis of trans-6,6a,7,8,9,13b-hexahydro-5H-benzo[d]naphth[2,1-b]azepines as rigid analogues of beta-phenyldopamine.

In an effort to define further the active geometry of the beta-phenyldopamine pharmacophore of certain dopamine D1 agonists, the title compounds have been synthesized as conformationally restricted homologues of the potent benzophenanthridine dopamine D1 agonist dihydrexidine 4a. The dihydroxy secondary amine 5b was evaluated as a potential agonist, whereas the N-methyl compounds 5a and 5c were hypothesized to be antagonists. Surprisingly, none of the three compounds had high affinity for dopamine D1 or D2 receptors. A comparison of the low-energy conformations of these molecules shows that the pendant phenyl ring of 5b is twisted about 28 degrees relative to that of the corresponding ring of 4a. Further, the additional methylene used to expand the C ring of 5b projects toward the alpha face of the molecule, perhaps suggesting that steric protrusion in this region of the molecule is not tolerated. Finally, the phenethylamine fragment incorporated into these molecules deviates about 30 degrees from the antiperiplanar conformation postulated to be necessary for agonist activity. On the other hand, the potential antagonist molecules 5a and 5c were compared with the dopamine D1 antagonist SCH 39166 2. The conformations of the former two structures differ quite dramatically from that of 2. The most notable differences lie in the relative orientations of the pendant phenyl rings in the two series, as well as the fact that the ethylamine fragment in 2 approximates a gauche conformation, while the comparable orientation in 5a and 5c more nearly approaches an antiperiplanar conformation. These findings will be used to refine further the model of the dopamine D1 agonist receptor that we have previously developed.

9-Dihydroxy-2,3,7,11b-tetrahydro-1H-naph[1,2,3-de]isoquinoline: a potent full dopamine D1 agonist containing a rigid-beta-phenyldopamine pharmacophore.

The present work reports the synthesis and preliminary pharmacological characterization of 8,9-dihydroxy-2,3,7,11b-tetrahydro-1H-naph[1,2,3-de] isoquinoline (4, dinapsoline). This molecule was designed to conserve the essential elements contained in our D1 agonist pharmacophore model (i.e., position and orientation of the nitrogen, hydroxyls, and phenyl rings). It involved taking the backbone of dihydrexidine [3; (+/-)-trans-10, 11-dihydroxy-5,6,6a,7,8,12b-hexahydrobenzo[a] phenanthridine], the first high-affinity full D1 agonist, and tethering the two phenyl rings of dihydrexidine through a methylene bridge and removing the C(7)-C(8) ethano bridge. Preliminary molecular modeling studies demonstrated that these modifications conserved the essential elements of the hypothesized pharmacopore. Dinapsoline 4 had almost identical affinity (KI = 5.9 nM) to 3 at rat striatal D1 receptors and had a shallow competition curve (nH = 0.66) that suggested agonist properties. Consistent with this, in both rat striatum and C-6-mD1 cells, dinapsoline 4 was a full agonist with an EC50 of ca. 30 nM in stimulating synthesis of cAMP via D1 receptors. The design and synthesis of dinapsoline 4 provide a powerful test of the model of the D1 pharmacophore we have developed and provide another chemical series that can be useful probes for the study of D1 receptors. An interesting property of 3 is that it also has relatively high D2 affinity (K0.5 = 50 nM) despite having an accessory phenyl ring usually though to convey D1 selectivity. Dinapsoline 4 was found to have even higher affinity for the D2 receptor (K0.5 = 31 nM) than 3. Because of the high affinity of 4 for D2 receptors, it and its analogs can be powerful tools for exploring the mechanisms of "functional selectivity" (i.e., that 3 is an agonist at some D2 receptors, but an antagonist at others). Together, these data suggest that 4 and its derivatives may be powerful tools in the study of dopamine receptor function and also have potential clinical utility in Parkinson's disease and other conditions where perturbation of dopamine receptors is useful.

Synthesis and biological evaluation of a series of substituted benzo[a]phenanthridines as agonists at D1 and D2 dopamine receptors.

Dihydrexidine [4;(+/-)-trans-10,11-dihydroxy-5,6,6a,7,8, 12b-hexahydrobenzo[a]phenanthridine (DHX)], the first high-affinity full D1 agonist, also is known to have significant D2 activity. The present work reports the synthesis and pharmacological activity of a series of analogs substituted in the pendent phenyl ring (i.e., 2-, 3-, or 4-position). (+/-)-trans-2-Methyl-10,11-dihydroxy-5,6,6a,7,8, 12b-hexahydrobenzo[a]phenanthridine (5) was a high-affinity D1 agonist, having approximately 4-fold greater D1 vs D2 selectivity than DHX itself. All of the analogs containing a methyl or ethyl (but not a phenyl) substituent at the 2-, 3-, or 4-position had a pharmacological profile similar to that of the lead compound DHX (4). Each analog was found to be a high-affinity full agonist with moderate selectivity for the D1 receptor. It is apparent from these results that the D1 receptor can tolerate small substituents at the 2-, 3-, and 4-positions of the pendent phenyl ring. On the basis of earlier studies showing that N-alkylation increases D2 selectivity, the 3-methyl N-n-propyl and 4-methyl N-n-propyl compounds 11 and 13 were synthesized. While these analogs exhibited much higher affinity for the D2 receptor, surprisingly 4-methyl-N-propyl-DHX (13) exhibited high affinity for both the D1 and D2 receptors. It was subsequently established that this compound is a selective D3 ligand (110-fold selectivity for the D3 over D2 receptor). The results from these studies demonstrate that several of the hexahydrobenzo[a]phenanthridine derivatives are agonists with high intrinsic activity that may serve as powerful tools to explore the structural features that determine affinity and selectivity (relative to the D2 receptor) of drugs for D1 receptors.

Effect of ring fluorination on the pharmacology of hallucinogenic tryptamines.

A series of fluorinated analogues of the hallucinogenic tryptamines N,N-diethyltryptamine (DET), 4-hydroxy-N,N-dimethyltryptamine (4-OH-DMT, psilocin), and 5-methoxy-DMT was synthesized to investigate possible explanations for the inactivity of 6-fluoro-DET as a hallucinogen and to determine the effects of fluorination on the molecular recognition and activation of these compounds at serotonin receptor subtypes. The target compounds were evaluated using in vivo behavioral assays for hallucinogen-like and 5-HT(1A) agonist activity and in vitro radioligand competition assays for their affinity at 5-HT(2A), 5-HT(2C), and 5-HT(1A) receptor sites. Functional activity at the 5-HT(2A) receptor was determined for all compounds. In addition, for some compounds functional activity was determined at the 5-HT(1A) receptor. Hallucinogen-like activity, evaluated in the two-lever drug discrimination paradigm using LSD-trained rats, was attenuated or abolished for all of the fluorinated analogues. One of the tryptamines, 4-fluoro-5-methoxy-DMT (6), displayed high 5-HT(1A) agonist activity, with potency greater than that of the 5-HT(1A) agonist 8-OH-DPAT. The ED(50) of 6 in the two-lever drug discrimination paradigm using rats trained to discriminate the 5-HT(1A) agonist LY293284 was 0.17 micromol/kg, and the K(i) at [(3)H]8-OH-DPAT-labeled 5-HT(1A) receptors was 0.23 nM. The results indicate that fluorination of hallucinogenic tryptamines generally has little effect on 5-HT(2A/2C) receptor affinity or intrinsic activity. Affinity at the 5-HT(1A) receptor was reduced, however, in all but one example, and all of the compounds tested were full agonists but with reduced functional potency at this serotonin receptor subtype. The one notable exception was 4-fluoro-5-methoxy-DMT (6), which had markedly enhanced 5-HT(1A) receptor affinity and functional potency. Although it is generally considered that hallucinogenic activity results from 5-HT(2A) receptor activation, the present results suggest a possible role for involvement of the 5-HT(1A) receptor with tryptamines.

Evaluation of cis- and trans-9- and 11-hydroxy-5,6,6a,7,8,12b-hexahydrobenzo[a]phenanthridines as structurally rigid, selective D1 dopamine receptor ligands.

The present study reports the investigation of the D1 structure-relationships of certain cis- or trans-9- or 11-monohydroxy analogues of (+/-)-trans-10,11-dihydroxy-5,6,6a,7,8,12b-hexahydrobenzo[a] phenanthridine (8a, dihydrexidine), previously identified as the first full efficacy D1 dopamine receptor agonist. The monohydroxybenzo[a]phenanthridines were prepared from the appropriately substituted beta-tetralones using the methods described earlier for the synthesis of their catechol analogues. The 10-bromo 11-hydroxy derivative 9e was prepared by treatment of precursor 9c with bromine in chloroform. The affinities of these compounds for the D1 and D2 dopamine receptor classes and for their effects on adenylate cyclase activity were assessed in rat striatal membranes. In addition to producing only minimal increases in adenylate cyclase activity (< or = 15%), these phenolic derivatives generally had significantly lower affinities for D1 and D2 receptors (D1 IC50 > or = 102 nM, D2 IC50 > or = 210 nM) than did their catechol analogues. Further, compounds bearing a cis B/C-ring fusion displayed lower affinities than those bearing a trans configuration, paralleling the activity differences between the catechol analogues. The data for these rigid dopamine receptor ligands from the benzo[a]phenanthridine class lend additional support for the hypothesis that D1 agonist activity is optimized by a trans ring configuration that maintains the beta-phenyldopamine substructure in the "trans-beta-rotamer."

Conformational analysis of D1 dopamine receptor agonists: pharmacophore assessment and receptor mapping.

Compute-aided conformational analysis was used to characterize the agonist pharmacophore for D1 dopamine receptor recognition and activation. Dihydrexidine (DHX), a high-affinity full agonist with limited conformational flexibility, served as a structural template that aided in determining a molecular geometry that would be common for other more flexible, biologically active agonists. The intrinsic activity of the drugs at D1 receptors was assessed by their ability to stimulate adenylate cyclase activity in rat striatal homogenates (the accepted measure of D1 receptor activation). In addition, affinity data on 12 agonists including six purported full agonists (dopamine, dihydrexidine, SKF89626, SKF82958, A70108, and A77636), as well as six less efficacious structural analogs, were obtained from D1 dopamine radioreceptor-binding assays. The active analog approach to pharmacophore building was applied as implemented in the SYBYL software package. Conformational analysis and molecular mechanics calculations were used to determine the lowest energy conformation of the active analogs (i.e., full agonists), as well as the conformations of each compound that displayed a common pharmacophoric geometry. It is hypothesized that DHX and other full agonists may share a D1 pharmacophore made up of two hydroxy groups, the nitrogen atom (ca. 7 A from the oxygen of m-hydroxyl) and the accessory ring system characterized by the angle between its plane and that of the catechol ring (except for dopamine and A77636). For all full agonists (DHX, SKF89626, SKF82958, A70108, A77636, and dopamine), the energy difference between the lowest energy conformer and those that displayed a common pharmacophore geometry was relatively small (< 5 kcal/mol). The pharmacophoric conformations of the full agonists were also used to infer the shape of the receptor binding site. Based on the union of the van der Waals density maps of the active analogs, the excluded receptor volume was calculated. Various inactive analogs (partial agonists with D1 K0.5 > 300 nM) subsequently were used to define the receptor essential volume (i.e., sterically intolerable receptor regions). These volumes, together with the pharmacophore results, were integrated into a three-dimensional model estimating the D1 receptor active site topography.

Synthesis and molecular modeling of 1-phenyl-1,2,3,4-tetrahydroisoquinolines and related 5,6,8,9-tetrahydro-13bH-dibenzo[a,h]quinolizines as D1 dopamine antagonists.

New 1-phenyl-1,2,3,4-tetrahydroisoquinolines and related 5,6,8,9-tetrahydro- 13bH-dibenzo[a,h]-quinolizines were prepared as ring-contracted analogs of the prototypical 1-phenyl-2,3,4,5-tetrahydrobenzazepines (e.g., SCH23390) as a continuation of our studies to characterize the antagonist binding pharmacophore of the D1 dopamine receptor. Receptor affinity was assessed by competition for [3H]SCH23390 binding sites in rat striatal membranes. The 6-bromo-1-phenyltetrahydroisoquinoline analog 2 of SCH23390 1 had D1 binding affinity similar to that for the previously reported 6-chloro analog 6, whereas the 6,7-dihydroxy analog 5 had significantly lower D1 affinity. Conversely, neither 6-monohydroxy- (3) nor 7-monohydroxy-1-phenyltetrahydroisoquinolines (4) had significant affinity for the D1 receptor. These results demonstrate that 6-halo and 7-hydroxy substituents influence D1 binding affinity of the 1-phenyltetrahydroisoquinolines in a fashion similar to their effects on 1-phenyltetrahydrobenzazepines. The conformationally constrained 3-chloro-2-hydroxytetrahydrodibenzoquinolizine 9 had much lower affinity relative to the corresponding, and more flexible, 6-chloro-7-hydroxy-1-phenyltetrahydroisoquinoline 6. Similarly, 2,3-dihydroxytetrahydrodibenzoquinolizine 10 had much lower D1 affinity compared to dihydrexidine 14, a structurally similar hexahydrobenzo[a]phenanthridine that is a high-affinity full D1 agonist. Together, these data not only confirm the effects of the halo and hydroxy substitutents on the parent nucleus but demonstrate the pharmacophoric importance of both the nitrogen position and the orientation of the accessory phenyl ring in modulating D1 receptor affinity and function. Molecular modeling studies and conformational analyses were conducted using the data from these new analogs in combination with the data from compounds previously synthesized. The resulting geometries were used to refine a working model of the D1 antagonist pharmacophore using conventional quantitative structure-activity relationships and three-dimensional QSAR (CoMFA).

Synthesis and evaluation of 6,7-dihydroxy-2,3,4,8,9,13b-hexahydro-1H- benzo[6,7]cyclohepta[1,2,3-ef][3]benzazepine, 6,7-dihydroxy- 1,2,3,4,8,12b-hexahydroanthr[10,4a,4-cd]azepine, and 10-(aminomethyl)-9,10- dihydro-1,2-dihydroxyanthracene as conformationally restricted analogs of beta-phenyldopamine.

The present study was designed to define the geometry of the hydrophobic accessory region for binding of dopamine D1 receptor ligands and to assess the relative importance of ethylamine side chain conformation for receptor affinity. Three compounds, 6,7-dihydroxy-2,3,4,8,9,13b-hexahydro-1H-benzo[6,7]cyclohepta[1,2, 3-ef][3]benzazepine, 4, 6,7-dihydroxy-1,2,3,4,8,12b-hexahydroanthr[10,4a,4-cd]aze pin e, 5, and 10-(aminomethyl)-9,10-dihydro-1,2-dihydroxyanthracene, 6, were synthesized as conformationally restricted analogs of beta-phenyldopamine. Molecular modeling studies were performed to compare these three compounds with the high-affinity D1 agonists dihydrexidine (DHX), 2, and SKF 38393, 3. The beta-phenyl moieties in the target compounds are constrained by means of either an ethyl (4) or methylene (5 and 6) bridge. The compounds adopt minimum-energy conformations in which the beta-phenyl group is approximately -22 degrees (4), -12 degrees (5), and -30 degrees (6) from coplanarity with the catechol ring. These compounds also embody either a freely rotating (6) or a rigidified gauche (4 and 5) rotameric conformation of the dopamine ethylamine side chain, the latter nearly perfectly superimposible on the benzazepine portion of SKF 38393. Radioligand competition experiments showed that compounds 4, 5, and 6 have only micromolar affinity for both the D1 and D2 dopamine receptor subtypes. The low affinity of 4-6, relative to 2 and 3, may be due to improper orientation of the beta-phenyl moiety and provides important information about the three-dimensional orientation of the hydrophobic accessory binding domain of the dopamine D1 receptor. In addition, the negligible affinity of 6, as compared to 2 and 3, indicates that the rotameric positioning of the ethylamine side chain may not be a primary determinant of receptor affinity.

Dopaminergic benzo[a]phenanthridines: resolution and pharmacological evaluation of the enantiomers of dihydrexidine, the full efficacy D1 dopamine receptor agonist.

Racemic trans-10,11-dihydroxy-5,6,6a,7,8,12b- hexahydrobenzo[a]phenanthridine (2, dihydrexidine) was shown previously to be the first bioavailable full efficacy agonist at the D1 dopamine receptor. In addition to its full D1 agonist properties, 2 also is a good ligand for D2-like dopamine receptors. The profound anti-Parkinsonian actions of this compound make determination of its enantioselectivity at both D1 and D2 receptors of particular importance. To accomplish this, the enantiomers were resolved by preparation of diastereomeric (R)-O-methylmandelic acid amides of racemic trans-10,11-dimethoxy-5,6,6a,7,8,12b- hexahydrobenzo[a]phenanthridine 4 that were then separated by centrifugal chromatography. An X-ray analysis of the (-)-N-(R)-O-methylmandel diastereoamide revealed the absolute configuration to be 6aS,12bR. Removal of the chiral auxiliary and O,O-deprotection afforded enantiomeric amines that were then tested for biological activity. In striatal membranes, the (6aR,12bS)-(+)-enantiomer 2 had about twice the affinity of the racemate and 25-fold greater affinity than the (-)-enantiomer at the D1 receptor labeled by [3H]SCH23390 (K0.5s of 5.6, 11.6, and 149 nM, respectively). Similarly, the (+)-enantiomer 2 had about twice the affinity of the racemate for human D1 receptors expressed in transfected Ltk- cells. Functionally, the (+)-enantiomer of 2 was a full agonist, with an EC50 of 51 nM in activating striatal dopamine-sensitive adenylate cyclase versus 2.15 microM for the (-)-enantiomer. With respect to D2-like receptors, (+)-2 had a K0.5 of 87.7 nM in competing with [3H]spiperone at D2 binding sites in rat striatal membranes versus about 1 microM for the (-)-enantiomer. Together, these data demonstrate that both the D1 and D2 activities of dihydrexidine reside principally in the (6aR,12bS)-(+)-enantiomer. The results are discussed in the context of structure-activity relationships and conceptual models of the D1 receptor.

LSD and structural analogs: pharmacological evaluation at D1 dopamine receptors.

The hallucinogenic effects of lysergic acid diethylamide (LSD) have been attributed primarily to actions at serotonin receptors. A number of studies conducted in the 1970s indicated that LSD also has activity at dopamine (DA) receptors. These latter studies are difficult to interpret, however, because they were completed before the recognition of two pharmacologically distinct DA receptor subtypes, D1 and D2. The availability of subtype-selective ligands (e.g., the D1 antagonist SCH23390) and clonal cell lines expressing a homogeneous receptor population now permits an assessment of the contributions of DA receptor subtypes to the DA-mediated effects of LSD. The present study investigated the binding and functional properties of LSD and several lysergamide and analogs at dopamine D1 and D2 receptors. Several of these compounds have been reported previously to bind with high affinity to serotonin 5HT2 (i.e., 3H-ketanserin) sites in the rat frontal cortex (K0.5 5-30 nM). All tested compounds also competed for both D1-like (3H-SCH 23390) and D2-like (3H-spiperone plus unlabeled ketanserin) DA receptors in rat striatum, with profiles indicative of agonists (nH < 1.0). The affinity of LSD and analogs for D2 like receptors was similar to their affinity for 5HT2 sites. The affinity for D1 like receptors was slightly lower (2- to 3-fold), although LSD and several analogs bound to D1 receptors with affinity similar to the prototypical D1 partial agonist SKF38393 (K0.5 ca. 25 nM). A second series of experiments tested the binding and functional properties of LSD and selected analogs in C-6 glioma cells expressing the rhesus macaque D1A receptor.(ABSTRACT TRUNCATED AT 250 WORDS)

Short- and long-term heterologous sensitization of adenylate cyclase by D4 dopamine receptors.

The D4 dopamine receptor, a member of the D2-like dopamine receptor family, may be important in the etiology and treatment of schizophrenia. The present study was designed to examine the effects of dopamine agonist exposure on adenylate cyclase activity in HEK293 cells stably expressing recombinant-D4 receptors. Two hour pretreatment with dopamine receptor agonists resulted in heterologous sensitization of forskolin-stimulated cyclic AMP accumulation in intact cells expressing the D4.2, D4.4, or D4.7 dopamine receptor variant. The potency and efficacy of dopamine for sensitization of cyclic AMP accumulation was comparable at all D4 receptor variants. D4 dopamine receptor-mediated sensitization was blocked by the D4 antagonist, clozapine, and prevented by overnight pretreatment with pertussis toxin, implying a role for Gi/Go proteins in heterologous sensitization. Further, long-term (18 h) agonist exposure resulted in a greater degree of sensitization of forskolin-stimulated cyclic AMP accumulation in both intact cells and membrane preparations of cells expressing the D4 receptor, compared to 2 h agonist exposure, without altering the density of the receptors. In addition, long-term agonist exposure decreased the abundance of Gialpha without altering the abundance of Gsalpha, whereas short-term agonist treatment had no effect on the immunoreactivity of either G protein. In summary, long-term agonist-induced sensitization of adenylate cyclase by the D4 receptor may involve mechanisms that do not contribute to short-term sensitization.

Impaired cholera toxin relaxation with age in rat aorta.

Beta-adrenergic-mediated vasorelaxation declines with maturation and aging. Available data suggest that impaired stimulatory G-protein function could explain this deficit. We have previously found a loss of cholera toxin (CT)-stimulated adenosine diphosphate (ADP) ribosylation with age in rat aortic membrane preparations, without evidence for loss of the stimulatory alpha subunit of G protein (Gsalpha) by immunoblotting. The purpose of this investigation was to determine if cholera toxin-mediated vasorelaxation was also impaired with age. Aortic ring segments from 6 weeks, 6 months, 12 months, and 24 months old male F-344 rats were used. Contraction to KCl and phenylephrine was assessed along with relaxation to cholera toxin (azide-free), isoproterenol and forskolin. There were no age-related changes to KCl or phenylephrine contraction. There was a significant decrease with age in relaxation to isoproterenol. This loss with age was significantly greater with KCl-preconstricted vessels than phenylephrine-preconstricted vessels. There were no age-related changes in the relaxation to forskolin. There was a significant decrease with age in the maximal relaxation to cholera toxin as well as a rightward shift in the dose-response curve. Cholera toxin-stimulated adenosine 3', 5'-cyclic phosphate (cAMP) levels were measured and there was no increase in cAMP levels surrounding the time period associated with relaxation induced by cholera toxin. These data suggest that different preconstricting agents markedly affect the age-related changes in beta-adrenergic-mediated vasorelaxation. Furthermore, they suggest that the mechanism of cholera toxin-mediated vasorelaxation may not be mediated through increases in cAMP concentration.

Hexahydrobenzo[a]phenanthridines: novel dopamine D3 receptor ligands.

We report that certain substituted hexahydrobenzo[a]phenanthridines are novel high affinity ligands selective for the dopamine D3 receptor. These data demonstrate that substitutions on the heterocyclic nitrogen and the pendant phenyl ring of this nucleus cause a marked increase in both affinity and selectivity for dopamine D3 vs. D2 receptors. Thus, these compounds represent important new tools to study the pharmacology of dopamine D3 receptors, and may also provide an opportunity for the synthesis of new radioligands for dopamine D3 receptors.

Dopamine D1 receptors: efficacy of full (dihydrexidine) vs. partial (SKF38393) agonists in primates vs. rodents.

Although partial efficacy dopamine D1 receptor agonists have little therapeutic benefit in parkinsonism, the first high potency, full efficacy dopamine D1 receptor agonist dihydrexidine recently has been shown to have profound antiparkinsonian effects. One reason for the greater antiparkinsonian effects of dihydrexidine vs. SKF38393 might be that SKF38393, while a partial dopamine D1 receptor agonist in rodent striatal preparations, has virtually no agonist activity in monkey striatum (Pifl et al., 1991, Eur. J. Pharmacol. 202, 273). To explore this hypothesis, we compared the dopamine D1 receptor affinity and efficacy of dihydrexidine and SKF38393 in striatum from rat and monkey. In vitro binding studies using membranes from putamen of adult rhesus monkeys demonstrated that dihydrexidine competed for dopamine D1 receptors (labeled with [3H]SCH23390) with high potency (IC50 = 20 nM vs. ca. 10 nM in rat brain). SKF38393 was about 4-fold less potent than dihydrexidine in both monkey and rat brain. The in vitro functional activity of these drugs was assessed by their ability to stimulate adenylate cyclase activity in tissue homogenates. Dihydrexidine was of full efficacy (relative to dopamine) in stimulating cAMP synthesis in both monkey and rat. SKF38393 was only a partial efficacy agonist in both rat striatum and monkey putamen, but contrary to the original hypothesis, it had the same efficacy (ca. 40% relative to dihydrexidine) in membranes from both species. Interestingly, greater between-subject variation was found in the stimulation produced by SKF38393 in primate compared to rat brain, although the basis for this variation is unclear.(ABSTRACT TRUNCATED AT 250 WORDS)