Good Receptor Affinity Research Articles

Design, synthesis, and biological evaluation of a potential long-acting glucagon-like peptide-1 (GLP-1) analog

By binding to its receptor, glucagon-like peptide-1 (GLP-1) plays various physiological roles, including activating glucose-dependent insulin secretion, inhibiting gastric emptying, and reducing appetite. This suite of activities makes GLP-1 and its analogs an attractive choice for treating type 2 diabetes mellitus in the context of overweight or obesity. This study used different types and lengths of fatty acids to design dual fatty acid side chains for GLP-1 receptor agonists including decanoic, dodecanoic, tetradecanoic, hexadecanoic, dodecanedioic, tetradecanedioic, hexadecanedioic, and octadecanedioic acids. Sixteen GLP-1 receptor agonists (conjugates 13–28) with dual fatty acid side chains were obtained by liquid-phase synthesis. After structural confirmation using high-resolution mass spectrometry, peptide mapping, and circular dichroism, the biological activities of the conjugates were screened. First, the conjugates were screened for albumin binding and activity in GLP-1R-CRE-bla CHO-K1 cells. Albumin binding results suggested a synergistic effect between the two fatty acids in the conjugates. Next, conjugates 18, 19, and 21 selected after primary screening were assessed for receptor affinity, activity in INS-1 cells, plasma stability across different species, and efficacy and pharmacokinetics in normal and db/db mice. One candidate (conjugate 19) was found to have albumin binding of >99 %, good receptor affinity, activities of INS-1 cells, and plasma stability. We found that cellular activities in GLP-1R-CRE-bla CHO-K1 cells and pharmacodynamics and pharmacokinetics in normal and db/db mice for conjugate 19 were superior to those of semaglutide.

SAR of biphenyl carboxamide ligands of the human melanin-concentrating hormone receptor 1 (MCH R1): Discovery of antagonist SB-568849

We report here the discovery of a class of MCH R1 ligands based on a biphenyl carboxamide template. A docked-in model is presented indicating key interactions in the putative binding site of the receptor. Parallel high throughput synthetic techniques were utilised to allow rapid exploration of the structure–activity relationship around this template, leading to compound SB-568849 which possessed good receptor affinity and selectivity. This compound proved to be an antagonist with stability in vivo, an acceptable brain–blood ratio and oral bioavailability.

1-Acyl-4-benzyl-2,5-transdimethyl-piperazine CCR1 antagonists

Two applications claim 1-acyl-4-benzyl-2,5-dimethylpiperazine derivatives as CCR1 antagonists useful in the treatment of inflammatory diseases. The two applications respectively claim compounds in which the acyl groups are 2-heteroaryl or cinnamoyl (and certain heterocyclic analogues thereof). Both applications describe compounds with good receptor affinity and good in vivo pharmacokinetic properties, displaying a superior profile relative to closely related prior art compounds.

Structure-activity studies including a Psi(CH(2)-NH) scan of peptide YY (PYY) active site, PYY(22-36), for interaction with rat intestinal PYY receptors: development of analogues with potent in vivo activity in the intestine.

Peptide YY (PYY) is a gut hormone that inhibits secretion and promotes absorption and growth in the intestinal epithelium. We have performed structure-activity studies with the active site, N-alpha-Ac-PYY(22-36)-NH(2), for interaction with intestinal PYY receptors. Investigation of aromatic substitutions at position 27 resulted in analogues that exhibited potent in vitro antisecretory potencies with N-alpha-Ac-[Trp(27)]PYY(22-36)-NH(2) exhibiting even greater potency than intact PYY. In vivo studies in dogs revealed that this analogue also promoted intestinal absorption of water and electrolytes during continuous intravenous and intraluminal infusion. Investigations carried out to identify features that would enhance stability revealed that incorporation of Trp(30) increased affinity for PYY receptors. A "CH(2)-NH" scan revealed that incorporation of reduced bonds at position 28-29 or 35-36 imparted greater receptor affinity. In general, disubstituted analogues designed based on the results of single substitutions exhibited good receptor affinity with N-alpha-Ac-[Trp(27),CH(2)-NH(35-36)]PYY(22-36)-NH(2) having the greatest affinity (IC(50) = 0.28 nM). Conservative multiple substitutions with Nle-->Leu and Nva-->Val also imparted good affinity. An analogue designed to encompass most of the favored substitutions, N-alpha-Ac-[Nle(24,28),Trp(30),Nva(31), CH(2)-NH(35-36)]PYY(22-36)-NH(2), exhibited a proabsorptive effect in dogs comparable to, but longer lasting than, that of intact hormone. Selected analogues also exhibited good antisecretory potencies in rats with N-alpha-Ac-[Trp(30)]PYY(22-36)-NH(2) being even more potent than PYY. However, the potencies did not correlate well with the PYY receptor affinity or the proabsorptive potencies in dogs. These differences could be due to species effects and/or the involvement of multiple receptors and neuronal elements in controlling the in vivo activity of PYY compounds. PYY(22-36) analogues exhibited good affinity for neuronal Y2 receptors but poor affinity for Y1 receptors. Also, crucial analogues in this series hardly bound to Y4 and Y5 receptors. In summary, we have developed PYY(22-36) analogues which, via interacting with intestinal PYY receptors, promoted potent and long-lasting proabsorptive and antisecretory effects in in vivo models. These compounds or analogues based on them may have useful clinical application in treating malabsorptive disorders observed under a variety of conditions.

Pharmacological characterization of H3 receptor antagonists with imidazole, thioimidazole and thioimidazoline polar groups in the side chain.

The third histamine receptor, initially seen as a central presynaptic autoreceptor, is currently recognised as an auto and heteroreceptor with the function of a general inhibitory brake in the cellular communications in neuronal and extraneuronal tissues [1]. The evidence that the H3 receptors are widely distributed in the brain and that they are tonically activated by histamine opened important perspectives for potential applications of H3-ligands in the treatment of different central disorders. The most recent data seem to indicate that H3 antagonism can favourably influence cognitive and learning functions, can normalize motor disturbances and can represent a new approach for the development of antiepileptic and antiobesity drugs [2]. Several H3 antagonists have been developed, but there remains a need to identify new molecules combining improved brain penetration, tolerability and good receptor affinity and selectivity. Proceeding from the study evaluating the pharmacological properties of original H3 blockers [3], we characterized in vitro the potency, affinity and selectivity at H3 histamine receptors of a series of imidazole derivatives with different degrees of basicity due to the presence of distinct polar groups in the side chain of variable length (Table 1). Further in vitro tests were performed to assess the possible interactions of the compounds at the guinea-pig ileal 5-HT3, a2 and M3 receptors.

Structure–property relationships on histamine H 3-antagonists: binding of phenyl-substituted alkylthioimidazole derivatives to rat plasma proteins

The binding of a series of H 3-antagonists to rat plasma proteins was investigated by dialysis experiments, with RP-HPLC measurement of the free ligand. The series was composed of 4(5)-phenyl-2-[[2-[4(5)-imidazolyl]ethyl]thio]imidazoles having, on the phenyl ring, meta- and para-substituents, with different physico-chemical characteristics. As high protein binding had been proposed as being one of the features limiting brain access for the reference H 3-antagonist thioperamide, the title series was employed to test the possibility of achieving lower protein binding by modulation of lipophilicity, while maintaining good receptor affinity. The compounds tested showed quotas of bound drug ranging from 60 to 97.5%, while for thioperamide a 78% bound drug quota was observed at high total concentrations, with a steep increase in bound percentage at lower concentrations. Two of the tested compounds, having a carboxamide substituent, showed lower protein binding compared to thioperamide over a wide range of total concentration, without a significant loss in affinity with respect to the parent compound. A strict dependence of protein binding on lipophilicity was observed, and a QSPR model was derived which could also account for the protein binding observed for thioperamide, while receptor affinity had been reported to be quite insensitive to phenyl ring substitution. It is therefore possible to modulate protein binding of these H 3-antagonists, through lipophilicity adjustment, without losing receptor affinity; this finding could help in the design of new compounds with improved brain access.

A proposed model of bradykinin bound to the rat B2 receptor and its utility for drug design.

A putative model of bradykinin bound to the rat B2 receptor was generated using a combination of homology modeling (from the known transmembrane structure of bacteriorhodopsin), energy minimization, molecular dynamics, and a two-stage conformational search as a docking simulation. Overall, the proposed bound ligand adopts a twisted "S" shape, wherein a C-terminal beta-turn is buried in the receptor just below the extracellular boundary of the cell membrane and the N-terminus is interacting with negatively charged residues in extracellular loop 3 of the receptor (most notably Asp268 and Asp286). Mutagenesis experiments describing mutations which result in both a loss of bradykinin affinity as well as those which have no effect on bradykinin affinity are in good agreement with the proposed structure. In short, the mutagenesis results and the computational simulations each point to the same region of the receptor as likely to bind bradykinin. A double mutation, predicted as being likely to have a dramatic effect on bradykinin binding affinity, was confirmed experimentally, adding some validation to the proposed complex. Moreover, a new pseudopeptide bradykinin receptor antagonist (D-Arg0-Arg1-[12-aminododecanoyl]2- Ser3-D-Tic4-Oic5-Arg6) was designed on the basis of the model, and found to have good receptor affinity. Speculation regarding other possible sites for mutagenesis are also described.

Development of a novel class of cyclic hexapeptide oxytocin antagonists based on a natural product.

A new structural class of cyclic hexapeptide oxytocin antagonists derived from Streptomyces silvensis and typified by L-365,209 (cyclo-[L-prolyl1-D-phenylalanyl2-L- isoleucyl3-D-dehydropiperazyl4-L-dehydroperazyl5-D-(N- methyl)phenylalanyl6]) was recently reported. In this paper we further delineate the structure-activity profile for this new class by systematic study of L-365,209 analogs obtained by total synthesis. The optimal combination of cyclic amino acid ring sizes at positions 1, 4, and 5 and the role of the N-alkyl substituent at position 6 was elucidated. The lipophilic amino acids at positions 2 and 3 and the unusual amino acid D-dehydropiperazic acid at position 4 were found to be the most critical residues for obtaining good oxytocin receptor affinity. Analogs containing a basic side chain at the less critical 5- and 6-positions maintained good receptor affinity and also had useful levels of water solubility for intravenous formulation. By combining potency- and solubility-enhancing substitutions, several analogs were identified that have the desired combination of properties in vitro (22, cyclo-[L-prolyl-D-tryptophanyl-L-isoleucyl-D-pipecolyl-L-pipeco lyl-D- histidyl]; 25, cyclo-[L-prolyl-D-2-naphthylalanyl-L-isoleucyl-D-pipecolyl-L -pipecolyl-D- histidyl]; 26, cyclo-[L-prolyl-D-tryptophanyl-L-isoleucyl-D-dehydropiperazyl-L-++ pipecolyl-D-histidyl]; 33, cyclo-[L-prolyl-D-tryptophanyl-L-isoleucyl-D-pipecolyl-L- piperazinylcarboxy-D-(N-methyl)phenylalanyl]; 34, cyclo-[L-prolyl-D-phenylalanyl-L-isoleucyl-D-dehydropiperazyl-L-or nithyl- D-(N-methyl)phenylalanyl]). In general, this class exhibited good selectivity for binding to the oxytocin receptor versus the arginine vasopressin V1a and V2 receptor subtypes, although increased V2 receptor affinity was observed in one case (32, cyclo[L-prolyl-D-2-naphthylalanyl-L-isoleucyl-D-pipecolyl-L- lysyl-D-(N- methyl)phenylalanyl]). Unexpectedly, compound 33 was found to stimulate contractions of the isolated rat uterus via activation of the uterine bradykinin receptor. Compounds 22, 25, 26, 33, and 34 were found to be potent antagonists of oxytocin-stimulated contraction of the rat uterus in vitro and in vivo. Compounds 22 and 25 were additionally characterized as potent antagonists of oxytocin-stimulated uterine contractions in the near-term pregnant rhesus monkey. These studies thus demonstrate the selectivity and efficacy of certain members of this novel class of antagonists and suggest their use as pharmacological tools in further defining the role of oxytocin in both term and preterm labor.

Estrogen receptor binding affinity and uterotrophic activity of triphenylhaloethylenes

Radiohalogenated estrogens have considerable potential for estrogen receptor-directed imaging and therapy for cancers which contain such receptors. In an effort to evaluate the potential of the triphenyl ethylene structure for such purposes we have synthesized 3 series of 2-halosubstituted triphenylethylenes containing oxygen functions in the 4 position of both aromatic rings attached to carbon 1 of the ethylene and tested their uterotrophic activity and competition for rat uterine low salt extractable, “cytosol” estrogen receptor. Most active, both as competitors for estradiol binding to estrogen receptors and by their ability to stimulate uterine growth are the 1,1- bis-4-hydroxyphenyl derivatives although the 1,1- bis-4-acetoxyphenyl derivatives also show good receptor affinity and demonstrate uterotrophic activities. However, since uterine cytosol contains enzymes which hydrolyze the acetates to the free phenols even during the incubation in the cold used for the competitive binding studies, a significant portion of the competition shown by the diacetates is probably due to their hydrolysis products, the free phenols. The 1,1- bis-4-methoxyphenyl derivatives are weak competitive binders and demonstrate uterotrophic activity only when administered at the higher, 20 μg, doses. Comparing the relative activities of various halogens at the 2 position, in each series the bromo and chloro derivatives generally were of similar activity and significantly more active than the corresponding iodo derivative. The non-halogen substituted derivatives were very good competitors for estrogen receptor binding but less active with regard to uterine growth stimulation, providing evidence that in vivo the vinyl halides would appear to be relatively stable to simple dehalogenation. Since they show reasonably good apparent affinities for the estrogen receptor and apparent in vivo stability, reflected by estrogenic activity, these halogen substituted triphenylethylene derivatives appear to be promising substrates for investigations of estrogen receptor directed imaging and therapy.