Heterocyclic analogues of N-(4-(4-(2,3-dichlorophenyl)piperazin-1-yl)butyl)arylcarboxamides with functionalized linking chains as novel dopamine D3 receptor ligands: potential substance abuse therapeutic agents.

Dopamine D3 receptor antagonists and partial agonists have been shown to modulate drug-seeking effects induced by cocaine and other abused substances. Compound 6 [PG01037, (N-(4-(4-(2,3-dichlorophenyl)piperazin-1-yl)-trans-but-2-enyl)-4-pyridine-2-ylbenzamide)] and related analogues are currently being evaluated in animal models of drug addiction. In these studies, a discrepancy between in vitro binding affinity, in vivo occupancy, and behavioral potency has been observed.

Reciprocal mutations in TM2/TM3 in a D2 dopamine receptor background confirms the importance of this microdomain as a selective determinant of para-halogenated 1,4-disubstituted aromatic piperazines.

We recently demonstrated that in the D4 dopamine receptor the aromatic microdomain that spans the interface of the second and third transmembrane (TM) domains influences the high affinity interactions of extremely D4-selective ligands possessing a 1,4-disubstituted aromatic piperazine/piperidine (1,4-DAP) structure. On the basis of their substructural features and patterns of sensitivity to mutations constructed in a D4 receptor background, the D4-selective 1,4-DAPs were categorized as having two distinct modes of binding that we named mode-1 and mode-3 [1]. Here we extend these findings of the ligand-receptor structure-affinity relationships for some of these highly D4-selective 1,4-DAPs by measuring the effect of the corresponding reciprocal TM2/TM3 mutations constructed in a D2 dopamine receptor background on the binding affinity of the para-halogenated mode-1 ligands L750,667 and FAUC213.

Dopamine receptor microdomains involved in molecular recognition and the regulation of drug affinity and function.

A cationic protonatable amine moiety on dopaminergic ligands forms a high affinity reinforced ionic bond with an anionic aspartic acid at position 3.32 of dopamine receptors. When present, catechol hydroxyls of the ligands form hydrogen bonds with serines at position 5.

A comparison of the mu-conotoxins by [3H]saxitoxin binding assays in neuronal and skeletal muscle sodium channel.

Sodium channels from rat brain, rat skeletal muscle, chick brain, and eel electroplax were compared by using the mu-conotoxins GIIIA, PIIIA, and StIII and [3H]saxitoxin. Rat skeletal muscle and eel electroplax sodium channels are equally sensitive to GIIIA, PIIIA, and StIII, displacing >90% of the [3H]saxitoxin binding sites in rat skeletal muscle and eel electroplax membranes and exhibiting inhibitory concentrations at half-maximal percentage specific binding (IC50) of 0.97 nM for GIIIA, 1.