Conformational analysis of enkephalin analogs containing a disulfide bond. Models for delta- and mu-receptor opioid agonists

Conformational analysis of the cyclic opioids H-Tyr-D-Pen-Gly-Phe-D-Pen-OH (DPDPE) and H-Tyr-D-Cys-Gly-Phe-D-Cys-OH (DCDCE) have been performed using the AMBER program. DPDPE is considerably more selective for delta-receptors than DCDCE. Using the RNGCFM program, a large number of ways were found to close the 14-membered disulfide-containing ring structure. However, intramolecular hydrogen bonds were only possible in gamma-turn and inverse gamma-turn conformations centered on the glycine residue which were associated with opposite chiralities of the disulfide bond. With the cyclic part of the molecules in either a gamma-turn or inverse gamma-turn, a systematic conformational analysis was performed on the tyrosine and phenylalanine sidechains. This showed that conformers with the tyrosine and phenylalanine phenyl rings in the vicinity of the disulfide bond were preferred due to attractive van der Waals forces. For DPDPE, however, this was only possible with a positive dihedral angle for the disulfide bond due to the presence of the beta-carbon methyls of Pen2. In contrast, these preferred conformers were possible with both chiralities of the disulfide bond in DCDCE. Conformational entropies and free energies were computed from the translational, rotational, and vibrational energy levels available to each conformer. The conformational entropies were found to vary significantly and to result in a re-ordering of the lowest energy minima. Based on these conformational differences in DPDPE and DCDCE and their differing pharmacological selectivities, tentative conformational preferences for delta- and mu-receptor opioid peptides are proposed.     

Conversion of A3 adenosine receptor agonists into selective antagonists by modification of the 5'-ribofuran-uronamide moiety

The highly selective agonists of the A(3) adenosine receptor (AR), Cl-IB-MECA (2-chloro-N(6)-(3-iodobenzyl)-5'-N-methylcarboxamidoadenosine), and its 4'-thio analogue, were successfully converted into selective antagonists simply by appending a second N-methyl group on the 5'-uronamide position. The 2-chloro-5'-(N,N-dimethyl)uronamido analogues bound to, but did not activate, the human A(3)AR, with K(i) values of 29 nM (4'-O) and 15 nM (4'-S), showing >100-fold selectivity over A(1), A(2A), and A(2B)ARs. Competitive antagonism was demonstrated by Schild analysis. The 2-(dimethylamino)-5'-(N,N-dimethyl)uronamido substitution also retained A(3)AR selectivity but lowered affinity.     

Pyrrolo- and pyridomorphinans: Non-selective opioid antagonists and delta opioid agonists/mu opioid partial agonists

Opioid ligands have found use in a number of therapeutic areas, including for the treatment of pain and opiate addiction (using agonists) and alcohol addiction (using antagonists such as naltrexone and nalmefene). The reaction of imines, derived from the opioid ligands oxymorphone and naltrexone, with Michael acceptors leads to pyridomorphinans with structures similar to known pyrrolo- and indolomorphinans. One of the synthesized compounds, 5e, derived from oxymorphone had substantial agonist activity at delta opioid receptors but not at mu and/or kappa opioid receptors and in that sense profiled as a selective delta opioid receptor agonist. The pyridomorphinans derived from naltrexone and naloxone were all found to be non-selective potent antagonists and as such could have utility as treatments for alcohol abuse.     

The TIPP opioid peptide family: development of delta antagonists, delta agonists, and mixed mu agonist/delta antagonists

The discovery of the prototype delta opioid antagonists TIPP (H-Tyr-Tic-Phe-Phe-OH) and TIP (H-Tyr-Tic-Phe-OH) in 1992 was followed by extensive structure-activity relationship studies, leading to the development of analogues that are of interest as pharmacological tools or as potential therapeutic agents. Stable TIPP-derived delta opioid antagonists with subnanomolar delta receptor binding affinity and extraordinary delta receptor selectivity include TIPP[Psi] (H-Tyr-TicPsi[CH(2)NH]Phe-Phe-OH] and TICP[Psi] (H-Tyr-TicPsi[CH(2)NH]Cha-Phe-OH); Cha: cyclohexylalanine), which are widely used in opioid research. Theoretical conformational analyses in conjunction with the pharmacological characterization of conformationally constrained TIPP analogues led to a definitive model of the receptor-bound conformation of H-Tyr-Tic-(Phe-Phe)-OH-related delta opioid antagonists, which is characterized by all-trans peptide bonds. Further structure-activity studies revealed that the delta antagonist vs delta agonist behavior of TIP(P)-derived compounds depended on very subtle structural differences in diverse locations of the molecule and suggested a delta receptor model involving a number of different inactive receptor conformations. A further outcome of these studies was the identification of a new class of potent and very selective dipeptide delta agonists of the general formula H-Tyr-Tic-NH-X (X = arylalkyl), which are of interest for drug development because of their low molecular weight and lipophilic character. Most interestingly, TIPP analogues containing a C-terminal carboxamide group displayed a mixed mu agonist/delta antagonist profile, and thus were expected to be analgesics with a low propensity to produce tolerance and physical dependence. This turned out to be the case with the TIPP-derived mu agonist/delta antagonist DIPP-NH(2)[Psi] (H-Dmt-TicPsi[CH(2)NH]Phe-Phe-NH(2)); Dmt: 2',6'- dimethyltyrosine).     

Modulation of the process of habituation by single-component solutions of agonists of opiate mu-, delta-, kappa- and sigma-receptors

The modulating influence of such specific agonists of opiate mu-, delta-, kappa- and sigma-receptors as morphine, D-Ala2, D-Ley5-enkephaline (DADL), bremazocine, and SKF 10,047 as well as that of naloxone, their specific blockator, on habituation of orthodromic evoked potential in the visual cortical area was studied in turtles. In spite of equal degree of suppression of evoked potentials by the agonists used, their ability to modify habituation was different. Morphine, bremazocine and SKF 10,047 were of high effectivity while DADL was of low one.     

MCH receptor peptide agonists and antagonists

Melanin-concentrating hormone (MCH) is an important neuropeptide hormone involved in multiple physiological processes. Peptide derivatives of MCH have been developed as tools to aid research including potent radioligands, receptor selective agonists, and potent antagonists. These tools have been used to further understand the role of MCH in physiology, primarily in rodents. However, the tools could also help elucidate the role for MCHR1 and MCHR2 in mediating MCH signaling in higher species.     

Differential effects of selective opioid peptide antagonists on the acquisition of pavlovian fear conditioning.

Pretreatment with opioid antagonists enhances acquisition of Pavlovian fear conditioning. The present experiments attempted to characterize the type of opioid receptor responsible for this effect using a procedure that assessed the fear of rats to a chamber previously associated with electric shock (1 mA, 0.75 s). Freezing, a species-typical immobility, was employed as an index of fear. Two mu opioid antagonists, CTOP (40 ng) and naloxonazine (10 micrograms), enhanced conditioning. On the other hand, the kappa antagonist nor-binaltorphimine reduced conditioning. Two delta antagonist treatments (16-methyl cyprenorphine and naltrindole) had no reliable effect on acquisition. Thus the enhancement of conditioning appears to be mediated by mu receptors. Previous research has shown that the conditional fear produced by these procedures caused an analgesia that is also mediated by mu receptors. It is argued that the enhancement effect occurs because of an antagonism of this analgesia and that the analgesia normally acts to regulate the level of fear conditioning.     

Application of the message-address concept to the docking of naltrexone and selective naltrexone-derived opioid antagonists into opioid receptor models

A binding site model for the opioid family of G-protein coupled receptors (GPCRs) is proposed based on the message-address concept of ligand recognition. Using ligand docking studies of the universal opioid antagonist, naltrexone, the structural basis for ‘message’ recognition is explored across all three receptor types, μ, δ, and κ. The binding mode proposed and basis for selectivity are also rationalized using the naltrexone-derived ligands, naltrindole (NTI) and norbinaltorphimine (nor BNI). These ligands are docked to the receptor according to the common naltrexone core or message. The resulting orientation places key ‘address’ elements in close proximity to amino acid residues critical to selectivity among receptor types. Selectivity is explained by sequence differences in the μ, δ, and κ receptors at these recognition points. Support for the model is derived from site directed mutagenesis studies and ligand binding data for the opioid receptors and other related GPCRs. Special issue dedicated to Dr. Eric J. Simon     

Design of subtype selective melatonin receptor agonists and antagonists.

Studies of the physiological actions of melatonin have been hindered by the lack of specific, potent and subtype selective agonists and antagonists. In the present study, we describe the utility of a melanophore cell line from Xenopus laevis for exploring structure-activity relationships among novel melatonin analogues and report a novel MT2-selective agonist (IIK7) and MT2-selective receptor antagonist (K185). IIK7 is a potent melatonin receptor agonist in the melanophore model, and in NIH3T3 cells expressing human mt1 and MT2 receptor subtypes. In radioligand binding experiments IIK7 is 90-fold selective for the MT2 subtype. K185 is devoid of agonist activity, but acts as a competitive melatonin antagonist in melanophores. A low concentration (10(-9) M) antagonizes melatonin inhibition of forskolin stimulation of cyclic AMP in NIH3T3 cells expressing human MT2 receptors, but has no effect in cells expressing mt1 receptors. In binding assays, K185 is 140-fold selective for the MT2 subtype.     

Thermic response of selective muscarinic agonists and antagonists in rat

Effect of some selective agonists and antagonists of cholinergic M receptor subtypes on rectal temperature was investigated in rats at an ambient temperature of 25 degrees +/- 2 degrees C. Centrally administered acetylcholine (ACh) induced transient hypothermia, whereas the muscarinic M1 receptor agonists, arecholine (ip) and McN-A-343 (McN) (icv), induced sustained and dose-related hypothermia. However, the nonspecific muscarinic receptor agonist, oxotremorine, and physostigmine, induced hypothermia at a lower dose and hyperthermia, accompanied by tremors, at higher doses. The muscarinic M2 receptor agonist, carbachol (icv) also produced a dose-related dual effect, hyperthermia and hypothermia being induced by the lower and higher doses, respectively. The M1 receptor antagonists, scopolamine (ip) and pirenzepine (icv), induced hyperthermia, whereas the M2 receptor antagonists, gallamine (icv) and AF-DX 116 (AFDX) (ip), produced hypothermia. The hypothermic effects of ACh. arecholine, McN, physostigmine, oxotremorine and carbachol were attenuated by scopolamine and pirenzepine. However, although scopolamine also inhibited the hyperthermic and tremorogenic effects of the higher dose of oxotremorine, it had a synergistic effect with the hyperthermia-inducing higher dose of physostigmine. AFDX attenuated the hyperthermic effect of the lower dose of carbachol, indicating that it was M2 receptor-mediated. Hemicholinium, an ACh synthesis inhibitor, had a transient hypothermic effect followed by slight hyperthermia. However, it markedly antagonized the hypothermic effects of gallamine and AFDX, indicating that their effects were dependent upon the availability of neuronal ACh. The results indicate that cholinergic hypothermia is a function of central muscarinic M1 receptors, with the M2 receptors serving as automodulators.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of selective opioid agonists on feline colonic transit.

The mu agonist morphine and the non-specific opioid antagonist naloxone both may accelerate feline colonic transit; the effects of morphine are dose dependent. Kappa and delta receptor function was studied in the present work. Colonic transit of a radionuclide marker instilled into the cecum was quantitated for 6 hr in a crossover study. The delta agonist [D-Pen2,D-pen5]enkephalin (1 mg/kg, i.m.) prolonged the cecum and ascending colon half-emptying time by 337% (P less than 0.05), and delayed the progression of the geometric center over time. The kappa agonist U-50,488 (1 mg/kg, i.m.) had no apparent effect on the cecum and ascending colon, but delayed filling of the descending colon. Loperamide, an antidiarrheal agent, also delayed colonic transit. Thus, selective opioid agonists have both site and functional differences in their effect on feline colonic transit.     

The design and pharmacology of novel selective muscarinic agonists and antagonists

The muscarinic pharmacology of C1-methyl-substituted chiral compounds related to McN-A-343 and of (R)- and (S)-dimethindene has been studied. Among the McN-A-343 analogues, the (S)-enantiomers were more potent and had higher affinity than the (R)-isomers. The quaternary compound (S)-BN 228 was found to be the most potent M1-selective agonist known today (pEC50: M1/rabbit vas deferens = 7.83; M2/guinea-pig atria = 6.35; M3/guinea-pig ileum = 6.29). In both the atria and ileum the tertiary carbamate, (S)-4-F-MePyMcN, was a competitive antagonist (pA2 value = 7.39 and 6.82, respectively). In contrast, in rabbit vas deferens (S)-4-F-MePyMcN was a potent partial agonist (pEC50 = 7.22; apparent efficacy = 0.83). These results indicate that (S)-4-F-MePyMcN might be a useful tool to study M1 receptor-mediated effects involved in central cholinergic function. (S)-Dimethindene was a potent M2-selective antagonist (pA2 = 7.86/atria; pKi = 7.8/rat heart) with lower affinities for the M1 (pA2 = 6.36/rat duodenum; pKi = 7.1/NB-OK 1 cells), M3 (pA2 = 6.92/guinea-pig ileum; pKi = 6.7/rat pancreas) and M4 receptors (pKi = 7.0/rat striatum). It was more potent (up to 41-fold) than the (R)-isomer. In contrast, the stereoselectivity was inverse at ileal H1 receptors (pA2: (R)-isomer = 9.42; (S)-isomer = 7.48). Thus, (S)-dimethindene could be a valuable agent to test the hypothesis that M2 antagonists show beneficial effects in the treatment of cognitive disorders. It might also become the starting point for the development of diagnostic tools for quantifying M2 receptors in the CNS with PET imaging.     

Identification of selective neuropeptide Y2 peptide agonists

Activation of the NPY2 receptor to reduce appetite while avoiding stimulation of the NPY1 and NPY5 receptors that induce feeding provides a pharmaceutical approach to modulate food intake. The naturally occurring peptide PYY(3-36) is a nonselective NPY1, NPY2, and NPY5 agonist. N-terminal truncation of PYY to abrogate affinity for the NPY1 and NPY5 receptors and subsequent N-terminal modification with aminobenzoic analogs to restore NPY2 receptor potency results in a series of highly selective NPY2 receptor peptide agonists.     

The agonist paradox: agonists and antagonists of acetylcholine receptors and opioid receptors

In contrast to antagonists, agonists tend to induce considerable conformational changes in their receptors, resulting in opening of ion channels, either directly or via secondary messengers. These conformational transformations require great energy expenses. However, the experimentally determined free energies of complexation between agonists and receptors are often relatively smaller than those for the corresponding antagonists. To rationalize this so-called 'agonist paradox', which has not been clarified in the literature, we have developed an alternative model. Our model may help to discriminate between agonists and antagonists of the acetylcholine (ACh) and mu-opioid receptors. For this purpose, a series of ligands (1-18) have been analyzed both in structural terms and with respect to complexation geometry within the anionic binding sites of these two receptor types.     

Development of selective agonists and antagonists of P2Y receptors

Although elucidation of the medicinal chemistry of agonists and antagonists of the P2Y receptors has lagged behind that of many other members of group A G protein-coupled receptors, detailed qualitative and quantitative structure–activity relationships (SARs) were recently constructed for several of the subtypes. Agonists selective for P2Y₁, P2Y₂, and P2Y₆ receptors and nucleotide antagonists selective for P2Y₁ and P2Y₁₂ receptors are now known. Selective nonnucleotide antagonists were reported for P2Y₁, P2Y₂, P2Y₆, P2Y₁₁, P2Y₁₂, and P2Y₁₃ receptors. At the P2Y₁ and P2Y₁₂ receptors, nucleotide agonists (5′-diphosphate derivatives) were converted into antagonists of nanomolar affinity by altering the phosphate moieties, with a focus particularly on the ribose conformation and substitution pattern. Nucleotide analogues with conformationally constrained ribose-like rings were introduced as selective receptor probes for P2Y₁ and P2Y₆ receptors. Screening chemically diverse compound libraries has begun to yield new lead compounds for the development of P2Y receptor antagonists, such as competitive P2Y₁₂ receptor antagonists with antithrombotic activity. Selective agonists for the P2Y₄, P2Y₁₁, and P2Y₁₃ receptors and selective antagonists for P2Y₄ and P2Y₁₄ receptors have not yet been identified. The P2Y₁₄ receptor appears to be the most restrictive of the class with respect to modification of the nucleobase, ribose, and phosphate moieties. The continuing process of ligand design for the P2Y receptors will aid in the identification of new clinical targets.     

Morphiceptin and beta-casomorphin-5 analogues containing a reduced peptide bond: selective mu-receptor agonists and a novel mu antagonist, H-Tyr-Pro psi (CH2-NH)Phe-Pro-Gly-OH.

In order to prevent enzymatic degradation of beta-casomorphin-5 (1) and morphiceptin, reduced peptide bonds were incorporated at the 2-3 and 3-4 bonds, respectively. The analogues were synthesized by a combination of solid phase methodology and reductive alkylation of resin-bound peptide amines with Boc-amino acid aldehydes (Boc: tert-butyloxycarbonyl) in the presence of NaBH3CN. During reversed phase high pressure liquid chromatography purification, peak shape distortions could be observed. Epimerization was excluded, based on gas chromatography/mass spectroscopy analysis, which indicated acceptable levels of racemization (less than 3%) in the crude product. Instead, the phenomena could be attributed to slow cis/trans isomerizations originating from the Xxx-Pro bonds in the sequence. The presence of different conformational isomers was also established by 1H-nmr spectroscopy in DMSO-d6. All analogues showed high stability in blood plasma, enhanced binding affinity for the mu receptor, and very low binding to the delta receptor. While the Phe 3 psi(CH2-N)Pro4 analogues (3) and (5) displayed agonist activity, the Pro 2 psi(CH2-NH)Phe3 modified analogue (2) showed antagonist activity comparable to D-Phe-Cys-Tyr-D-Trp-Arg-Thr-Pen-Thr-NH2.     

Spinal administration of selective opioid antagonists in amphibians: evidence for an opioid unireceptor

In mammals, opioids act by interactions with three distinct types of receptors: mu, delta, or kappa opioid receptors. Using a novel assay of antinociception in the Northern grass frog, Rana pipiens, previous work demonstrated that selective mu, delta, or kappa opioids produced a potent antinociception when administered by the spinal route. The relative potency of this effect was highly correlated to that found in mammals. Present studies employing selective opioid antagonists, beta-FNA, NTI, or nor-BNI demonstrated that, in general, these antagonists were not selective in the amphibian model. These data have implications for the functional evolution of opioid receptors in vertebrates and suggest that the tested mu, delta, and kappa opioids mediate antinociception via a single type of opioid receptor in amphibians, termed the unireceptor.     

Novel phenylamino acetamide derivatives as potent and selective kappa opioid receptor agonists

A novel series of phenylamino acetamide derivatives was synthesized. These amides were shown to be potent and selective kappa opioid receptor agonists.     

The stimulation of food intake by selective agonists of mu, kappa and delta opioid receptors

It is known that under some conditions the administration of opioid agonists will stimulate food intake. However, the lack of receptor selectivity of some of the agonists which produce this effect leaves open the question of which receptor types are actually involved. In the experiments presented here, rats were given intracerebroventricular injections of Dynorphin 1-17 (DYN), [D-ala2MePhe4,-Gly-ol5]enkephalin (DAGO), and [D-ser2, leu5]enkephalin-thr6 (DSLET); these peptides are thought to be selective agonists at kappa, mu and delta opioid receptors, respectively. All three peptides stimulated food intake in non-deprived rats at doses in the 3-10 nmol range; water intake was also increased in some cases. Generally, DYN stimulated feeding at a lower dose than DAGO or DSLET and the magnitude of the effect tended to be greater. On the other hand, DAGO more consistently increased water intake. In some cases, DYN also caused episodes of "barrel-rolling" and postural abnormalities, whereas DAGO had sedative and/or cataleptic effects. These results are interpreted as an involvement of more than one opioid receptor types in the regulation of appetite, possibly with separate opioid systems contributing to food and water intake.