Gunnar Nordvall

Delineation of the peptide binding site of the human galanin receptor.

Galanin, a neuroendocrine peptide of 29 amino acids, binds to Gi/Go‐coupled receptors to trigger cellular responses. To determine which amino acids of the recently cloned seven‐transmembrane domain‐type human galanin receptor are involved in the high‐affinity binding of the endogenous peptide ligand, we performed a mutagenesis study. Mutation of the His264 or His267 of transmembrane domain VI to alanine, or of Phe282 of transmembrane domain VII to glycine, results in an apparent loss of galanin binding. The substitution of Glu271 to serine in the extracellular loop III of the receptor causes a 12‐fold loss in affinity for galanin. We combined the mutagenesis results with data on the pharmacophores (Trp2, Tyr9) of galanin and with molecular modelling of the receptor using bacteriorhodopsin as a model. Based on these studies, we propose a binding site model for the endogenous peptide ligand in the galanin receptor where the N‐terminus of galanin hydrogen bonds with Glu271 of the receptor, Trp2 of galanin interacts with the Zn2+ sensitive pair of His264 and His267 of transmembrane domain VI, and Tyr9 of galanin interacts with Phe282 of transmembrane domain VII, while the C‐terminus of galanin is pointing towards the N‐terminus of th

Substituted 7-Amino-5-thio-thiazolo[4,5-d]pyrimidines as Potent and Selective Antagonists of the Fractalkine Receptor (CX3CR1)

We have developed two parallel series, A and B, of CX3CR1 antagonists for the treatment of multiple sclerosis. By modifying the substituents on the 7-amino-5-thio-thiazolo[4,5-d]pyrimidine core structure, we were able to achieve compounds with high selectivity for CX3CR1 over the closely related CXCR2 receptor. The structure-activity relationships showed that a leucinol moiety attached to the core-structure in the 7-position together with α-methyl branched benzyl derivatives in the 5-position displayed promising affinity, and selectivity as well as physicochemical properties, as exemplified by compounds 18a and 24h. We show the preparation of the first potent and selective orally available CX3CR1 antagonists.

Interactions of ligands with active and inactive conformations of the dopamine D2 receptor

The affinities of 19 pharmacologically diverse dopamine D2 receptor ligands were determined for the active and inactive conformations of cloned human dopamine D2 receptors expressed in Ltk cells. The agonist [3H]quinpirole was used to selectively label the guanine nucleotide-binding protein-coupled, active receptor conformation. The antagonist [3H]raclopride, in the presence of the non-hydrolysable GTP-analogue Gpp(NH)p and sodium ions and in the absence of magnesium ions, was used to label the free inactive receptor conformation. The intrinsic activities of the ligands were determined in a forskolin-stimulated cyclic AMP assay using the same cells. An excellent correlation was shown between the affinity ratios (KR/KRG) of the ligands for the two receptor conformations and their intrinsic activity (r=0.96). The ligands included eight structurally related and enantiopure 2-aminotetralin derivatives; the enantiomers of 5-hydroxy-2-(dipropylamino)tetralin, 5-methoxy-2-(dipropylamino)tetralin, 5-fluoro-2-(dipropylamino)tetralin and 2-(dipropylamino)tetralin. The (S)-enantiomers behaved as full agonists in the cyclic AMP assay and displayed a large KR/KRG ratio. The (R)-enantiomers were classified as partial agonists and had lower ratios. The structure-affinity relationships of these compounds at the active and the inactive receptor conformations were analysed separately, and used in conjunction with a homology based receptor model of the dopamine D2 receptor. This led to proposed binding modes for agonists, antagonists and partial agonists in the 2-aminotetralin series. The concepts used in this study should be of value in the design of ligands with predetermined affinity and intrinsic activity.

Mutagenesis Study on Human Galanin Receptor GalR1 Reveals Domains Involved in Ligand Binding a

Abstract: Many receptor mutants were generated and several NH2‐terminally modified galanin analogs synthesized to define the regions of hGalR1 involved in galanin binding. Ligand binding properties and functionality of mutant receptors were evaluated. The His264Ala and Phe282Ala receptor mutants, although deficient in binding in the concentration range of galanin used, remained functional albeit at least 20‐fold less efficient than the wild‐type receptor in the inhibition of stimulated cAMP production. Hence, His264 and Phe282 of hGalR1 are directly involved in galanin binding. NH2‐terminal carboxylic acid analogs of galanin (1–16) have a very low affinity for the wild‐type receptor, but substantially increased affinity for the Glu271Lys‐hGalR1, suggesting that the NH2‐terminus of galanin binds to the receptor near the transmembrane (TM) VI. Based on these findings and computer‐aided molecular modeling, we propose a binding site model for the hGalR1 receptor (possibly also for other galanin receptor subtypes): galanin binds with its NH2‐terminus to the pocket between TM III and TM VI, Trp2 of galanin interacts with His264 of the receptor, and Tyr9 is involved in an aromatic‐aromatic type of interaction with Phe282 of ECIII of GalR1.

Molecular Design Using the Minireceptor Concept

Explicit molecular binding pockets were constructed and optimized around sets of superimposed ligands using the minireceptor concept. The resulting binding sites incorporate the properties of the different ligands and were shown to be suitable for the design of molecules presenting novel interaction patterns. Two applications of minireceptor construction and/or optimization, followed by molecular design are described. In the pursuit of new ligands mimicking the action of paclitaxel, a minireceptor was constructed using the primary amino acid sequence of the target protein as a guide. The active site extracted from a homology-based model of the serotonin 5-HT1A receptor was optimized around a set of three ligands using the same approach.

SYNTHESIS AND PHARMACOLOGY OF THE ENANTIOMERS OF UH301 : OPPOSING INTERACTIONS WITH 5-HT1A RECEPTORS

The (S)-enantiomer of 5-fluoro-8-hydroxy-2-(dipropylamino) tetralin [(S)-2a; (S)-UH301] was the first reported 5-HT1A receptor antagonist. We now give a full account on the synthetic effort leading to the preparation of the racemate and the enantiomers of 2a. The crystal and molecular structure of 2a. HBr has been determined by X-ray diffraction and the absolute configuration has been deduced using statistical tests of the crystallographic R values. The unit cell is tetragonal (P4(1)2(1)2) with a = b = 13.2235(2), c = 39.560(1) A and contains two crystallographically independent molecules in each asymmetric unit. The two solid state conformers differ in the conformation of the N-propyl groups. The pharmacological characterization of the enantiomers was done by use of in vivo biochemical and behavioural assays in rats. The (R)-enantiomer of 2a is a 5-HT1A receptor agonist of low potency while (S)-2a does not exhibit any agonist properties at 5-HT1A receptors. As a consequence of the opposing effects of the enantiomers, the racemate, rac-2a, does not produce any clear-cut effects in rats. The reduced efficacy of (S)-2a as compared to the well known 5-HT1A receptor agonist 8-hydroxy-2-(dipropylamino) tetralin (1;8-OH-DPAT) may be due to the fluoro-substituent induced negative potential of the aromatic ring.