Dermenkephalin and deltorphin I reveal similarities within ligand-binding domains of mu- and delta-opioid receptors and an additional address subsite on the delta-receptor.

Dermorphin (Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2), dermenkephalin (Tyr-D-Met-Phe-His-Leu-Met-Asp-NH2) and deltorphin I (Tyr-D-Ala-Phe-Asp-Val-Val-Gly-NH2) are the first naturally occurring peptides highly potent for and almost specific to the mu- and delta-opioid receptors, respectively. The amino-terminal domains Tyr-D-X-Phe (where X is either Ala or Met) of these peptides behave as selective and potent mu-receptor ligands. Routing of Tyr-D-X-Phe to the delta- or the mu- receptor is associated with the presence or the absence at the C-terminus of an additional hydrophobic and negatively charged tetrapeptide by-passing the mu-addressing ability of the amino-terminal moiety. A study of 20 Tyr-D-X-Phe-Y-NH2 analogs with substitution of X and Y by neutral, hydrophobic, aromatic amino acids as well as by charged amino acid residues shows that tetrapeptides maintain high binding affinity and selectivity for the mu-opioid receptor. Although residue in position 4 serves a delta-address function, the tripeptide motif at the C-terminus of dermenkephalin and deltorphin I are critical components for high selectivity at delta-opioid receptor. Results demonstrate that mu- and delta-opioid receptors share topologically equivalent ligand-binding domains, or ligand-binding sequences similarities, that recognized Tyr-D-X-Phe as a consensus message-binding sequence. The delta-receptor additionally contains a unique address subsite at or near the conserved binding domain that accommodates the C-terminal tetrapeptide motif of dermenkephalin and deltorphin I.     

Molecular determinants of receptor affinity and selectivity of the natural delta-opioid agonist, dermenkephalin

Processing of the polyprotein precursor pro-dermorphin generates two distantly related D-amino acid-containing peptides, dermorphin and dermenkephalin, which are among the most selective high affinity agonists described, respectively, for the mu- and delta-opioid receptors. Dermenkephalin, Tyr-D-Met-Phe-His-Leu-Met-Asp-NH2, is a linear, potentially flexible peptide devoid of structural homology with either enkephalins, endorphins, or dynorphins and, as such, represents a useful tool for identifying determinants of high affinity and selective binding of opioids to the delta-receptor. A series of selected dermenkephalin analogs and homologs was investigated for affinity at the mu- and delta-sites in the brain. Whereas dermenkephalin has high affinity and specificity for the delta-opioid receptors, its tetrapeptide amino end, dermenkephalin-[1-4]-NH2 binds almost exclusively at the mu-receptors. Dermorphin, Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2, is only marginally more selective for the u-sites than is dermenkephalin-[1-4]-NH2. Using dermorphin-dermenkephalin peptide hybrids and C-terminal deletion analogs of dermenkephalin, we showed the critical role that the C-terminal residues Met6 and Asp7 play in specifying correct addressing of dermenkephalin toward delta-receptors. The potent mu-deteminant located within the amino end of dermenkephalin is over-whelmed by the powerful delta-directing ability of the carboxy end. The negatively charged side chain of Asp7 makes a significant contribution to the delta-addressing ability of the C-terminal region, a finding consistent with Schwyzer's membrane selection model (Schwyzer, R. (1986) Biochemistry 25, 6335-6342). The Leu residue in position 5 and D-configuration about the alpha-carbon of Met2 were found to be of crucial importance for high affinity binding to delta-receptors. Whereas the Met residue in position 6 in dermenkephalin could safely be oxidized or replaced with D-Met, oxidation of Met2 led to deleterious effects, this analog being 1/100 as potent as dermenkephalin at delta-sites. Overall, the data collected demonstrate that highest levels of selectivity and affinity for the delta-opioid receptors can be achieved with small-sized, potentially flexible, linear peptides and further support the model according to which, in addition to optimum accommodation at the receptor, selection for delta-receptors is reduced by the effective positive charge of the molecule. Dermenkephalin may provide a starting point for the design of agonists and antagonists with nearly total specificity for the delta-sites. Such pharmacological agents could be used to explore the ill-defined physiological role and behavioral actions conveyed by delta-opioid receptors.     

The mu-selective heptapeptide opioid dermorphin has two conformations around Phe3 psi with no head-to-tail interaction. A quantitative 2-D NMR and molecular modeling analysis

The mu opioid heptapeptide Dermorphin (DRM) is under 70 % of trans forms for the Tyr(5)-Pro(6) peptide bond in solution (CDCl(3)/DMSO-d(6) 1/1 vol/vol). Variations of NOE integrals at 5 temperatures show apparent correlation times of 0.8 to 0.9 ns (at 280 K) in that mixed solvent. Four NOE between non-adjacent residues reveal a large population of folded structures. However, in trans DRM, 4 adjacent NOE Phe(3)/Gly(4) can only be explained by an equilibrium between folded (psi(3) > 0) and extended (psi(3) > 0) conformations. Simulated annealing modeling gave about 60% (psi(3) > 0) and 40% (psi(3) > 0) of these conformer populations. Trans DRM study and previous studies on the heptapeptide opioids, dermenkephalin (DREK) and deltorphin-I (delta selective), and DREK(1-4)-DRM(5-7) hybrid (mu selective), show in folded structures more backbone bending of the first 4 residues in the mu opioids than in the delta peptides. Also, the main difference between mu- and delta-opioid peptides is a large fraction of extended conformations in mu heptapeptides. Either bending of the N-terminus, or extension of the C-terminal part in mu-opioid heptapeptides prevent the head-to-tail interactions which allow delta-opioid peptides to bind selectively to the delta-opioid receptor.     

The delta-selective opioid peptide dermenkephalin and the mu-selective hybrid peptide dermenkephalin-[1-4]-dermophin-[5-7] display strikingly different conformations despite identical tetrapeptide N-termini. A quantitative 2-D NMR and molecular modeling analysis

The selective recognition of the aminoterminal binding pharmacophore Tyr-D-Xaa-Phe of the opioid heptapeptide dermorphin, Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2 (DRM)1, and of dermenkephalin, Tyr-D-Met-Phe-His-Leu-Met-Asp-NH2 (DREK), by the mu-opioid receptor and delta-opioid receptor, respectively, depends upon the constitution / conformation of the C-terminal tripeptide. The hybrid peptide DREK-[1-4]-DRM-[5-7] is very potent at, and exquisitely selective for the mu-opioid receptor, and differs only from dermenkephalin by its C-terminal tripeptide. Comparison of the structural features of DREK-[1-4]-DRM-[5-7] and dermenkephalin by nmr analysis and molecular modeling revealed striking differences, as well in the trans (Tyr5 - Pro6) isomer (population 75%) than in the cis isomer.. Whereas the folded C-terminal tail of dermenkephalin influenced the tertiary structure of the N-terminal tetrapeptide and placed the Tyr1 and Phe3 aromatic rings in definite orientations that are best suited for the delta-receptor, there were only weak contacts, as shown by NOE data, between the aminoterminal and carboxyterminal parts of the hybrid peptide. This promoted increased flexibility of the whole backbone and relaxed orientations for the side-chains of Tyr1 and Phe3 that are compatible with the mu-receptor but unsuitable for the delta-receptor. The steric hindrance introduced by Pro6 in DREK-[1-4]-DRM-[5-7], plus the absence of large hydrophobic side-chains in positions 5 and 6 may prevent close contacts between the N-terminal and C-terminal domains and reorientation of the main pharmacophoric elements Tyr1 and Phe3.     

Characterisation and visualisation of [3H]dermorphin binding to mu opioid receptors in the rat brain. Combined high selectivity and affinity in a natural peptide agonist for the morphine (mu) receptor

Dermorphin, Tyr-DAla-Phe-Gly-Tyr-Pro-Ser-NH2, a potent opioid peptide isolated from amphibian skin, is endowed with outstanding structural and biological features. It has no common structure with mammalian opioid peptides and is a unique example of a peptide, synthesized by an animal cell, which contains a D-amino acid in its native sequence. We have undertaken a complete evaluation of the receptor selectivity of dermorphin, together with the binding characteristics and receptor distribution of [3H]dermorphin in the rat brain. 1. Dermorphin was tested for its relative affinity to mu-, delta- and chi-opioid receptors by determining its potency in displacing the selective mu-receptor ligand [3H]Tyr-DAla-Gly-MePhe-Gly-ol (where Gly-ol = glycinol), the prototypic delta-receptor ligand [3H]Tyr-DPen-Gly-Phe-DPen (where DPen = beta, beta-dimethylcysteine) and the chi ligand [3H]ethylketocyclazocine from rat brain and/or guinea pig cerebellum membrane preparations. Inhibitory constant (Ki) values of dermorphin were 0.7 nM, 62 nM and greater than 5000 nM respectively for mu, delta and chi sites, indicating a selectivity ratio Ki(delta)/Ki(mu) = 88. Under similar conditions, Tyr-DAla-Gly-MePhe-Gly-ol, which is regarded as one of the most selective high-affinity mu-agonist available, exhibited a selectivity ratio of 84. 2. Specific binding properties of tritium-labeled dermorphin (52 Ci/mmol) were characterized in the rat brain. Equilibrium measurements performed over a large range of concentrations revealed a single homogeneous population of high-affinity binding sites (Kd = 0.46 nM; Bmax = 92 fmol/mg membrane protein). 3. Profound differences were observed in the potencies displayed by various selective opiates and opioids ligands in inhibiting the specific binding of [3H]dermorphin. The rank order of potency was in good agreement with that obtained with other mu-selective radiolabeled ligands. 4. Receptor autoradiography in vitro was used to visualize the distribution of [3H]dermorphin binding sites in rat brain. The labeling pattern paralleled that observed using other mu probes. Binding parameters and selectivity profile of [3H]dermorphin on slide-mounted sections were similar to those obtained with membrane homogenates. 5. Finally, intracerebroventricular administration of synthetic dermorphin into mice showed that this peptide is the most potent analgesic known to date, being up to 5 and 670 times more active than beta-endorphin and morphine, respectively. Higher doses induced catalepsy. The overall data collected demonstrate that dermorphin is the first among the naturally occurring peptides to be highly potent and nearly specific super-agonist towards the morphine (mu) receptor.(ABSTRACT TRUNCATED AT 400 WORDS)     

Delta opioid receptor-selective ligands: [D-Pen2,D-Pen5]enkephalin-dermenkephalin chimeric peptides.

A number of DPDPE-dermenkephalin chimeric peptides have been synthesized in which the putative C-terminal delta-address of dermenkephalin has been linked to the highly delta opioid selective cyclic peptide [D-Pen2,D-Pen5]enkephalin (DPDPE). Asp, Met-Asp and Leu-Met-Asp have been added to the C-terminus of DPDPE and both the carboxyl terminal and the carboxamide terminal series have been prepared. The bioassays using the mouse vas deferens and guinea pig ileum preparations have revealed a steady decrease in potency (compared to DPDPE) at delta and mu receptors as the dermenkephalin sequences were added. Some of the analogues, however, retained high delta selectivity. Similar results were obtained using radioligand binding assays. These findings suggest that the C-terminal amino acid sequence of dermenkephalin plays a role of delta-address which is specific to dermenkephalin itself, and is not additive with another delta selective ligand such as DPDPE.     

Characterization of the receptor binding profile of (3H)-dermorphin in the rat brain

Amphibian skin synthesizes a variety of biologically active peptides. Of these, dermorphin (Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2) is an extraordinarily potent opioid peptide up to 1000 times more active than morphine in inducing analgesia after intracerebroventricular administration. Dermorphin has little in common with the sequence of all hitherto known mammalian opioid peptides and is unique in having a D-amino acid residue in position 2. Specific binding properties of tritium labeled dermorphin were characterized in the rat brain. Scatchard or Hill analysis of equilibrium measurements performed over a large range of concentrations revealed a single population of dermorphin binding sites with a Kd value of 0.46 nM. Dermorphin and the selective mu-receptor ligand (D-Ala2, MePhe4, Gly5-ol)-enkephalin (DAGO) had similar high potencies in competing with (3H)-dermorphin binding, whereas the inverse holds for the prototypical delta receptor ligand (D-Pen2, D-Pen5)-enkephalin (DPDPE), which exhibited a potency three orders of magnitude lower. Dermorphin was tested for its relative affinity to mu and delta binding sites by determining its potency in displacing (3H)-DAGO and (3H)-DPDPE from rat brain membrane preparations. Based on these comparisons, dermorphin exhibited a selectivity ratio Ki(DPDPE)/Ki(DAGO) = 100, a value almost identical to that of DAGO, this ligand being considered as the protypical mu-receptor probe. The high affinity and selectivity of (3H)-dermorphin together with its very low nonspecific binding make this peptide a useful tool for dissecting the role(s) of the mu-receptor(s).     

Examination of the conformational meaning of "delta-address" in the dermenkephalin sequence

Comprehensive energy calculations were applied to four opioid-related peptides with different receptor selectivities, namely the delta-selective dermenkephalin (Tyr-D-Met-Phe-His-Leu-Met-Asp-NH2, DRE), the mu-selective dermorphin (Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2, DRM) and their "hybrid" peptides DRM/DRE (Tyr-D-Ala-Phe-Gly-Leu-Met-Asp-NH2) and DRE/DRM (Tyr-D-Met-Phe-His-Tyr-Pro-Ser-NH2). It was shown that the N-terminal tripeptide "mu-messages" in the delta-selective ligands DRE and DRM/DRE can possess similar low energy space arrangements of their functionally important elements (the N-terminal alpha-amino group and the aromatic moieties of Tyr and Phe), but that these are different from the space arrangement of these moieties in mu-selective DRM and DRE/DRM. These results suggest that the C-terminal tripeptide "delta-address" in DRE may influence the conformation of the "mu-message" in DRM. A refined model for the delta-receptor-bound conformation of DRE is proposed based on these calculations which is similar to that previously suggested for the cyclic delta-selective peptide [D-Pen2, D-Pen5]enkephalin (DPDPE). This model also has partial correspondence with the structure of the delta-selective alkaloid naltrindole.     

The effect of modification of the carboxyl group in short D-arginine 2-containing enkephalin analogs on their affinity and selectivity for opiate receptors

Radioreceptor binding assay using a membrane fraction from the rat brain was applied to study [D-Arg2, Leu5] enkephalin and two series of its analogues truncated at the C-terminus with a free or modified carboxyl group: tetra- and tripeptide amides and ethyl esters. The affinity to mu-specific opiate receptor subtype of the N-terminal [D-Arg2] tetrapeptide ethyl ester was 44 times as high as that of the tripeptide with a free carboxyl, and thus the ester retained up to 10% of leucine-enkephalin binding potency. However, a comparable esterification of the carboxyl group in the N-terminal [D-Arg2] tripeptide led to a 6-fold reduction in its affinity to mu-receptors. Consequently, identical modifications of the C-terminal carboxyl group in enkephalin analogues of various length can have completely different effects. Substitution of the natural glycine residue by D-arginine residue in position 2 of the enkephalin molecule truncated at the C-terminus increased the mu-receptor binding potency of the tetrapeptide, whereas its delta receptor binding potency declined by more than one order of magnitude. Simultaneous replacement of glycine2 by D-arginine2 and carboxyl amidation resulted in the short enkephalin analogue Tyr--D--Arg--Gly--Phe--NH2, whose affinity to mu receptors was four times as high as that of leucine--enkephalin, the tetrapeptide being 284 times more selective for the mu vs. delta opiate receptors.     

The μ-selective Heptapeptide Opioid Dermorphin has Two Conformations Around Phe3 Ψ with no Head-to-tail Interaction. A Quantitative 2-D NMR and Molecular Modeling Analysis

Abstract

The μ opioid heptapeptide Dermorphin (DRM) is under 70% of trans forms for the Tyr⁵-Pro⁶ peptide bond in solution (CDC1₃/DMSO-d₆ 1/1 vol/vol). Variations of NOE integrals at 5 temperatures show apparent correlation times of 0.8 to 0.9 ns (at 280 K) in that mixed solvent. Four NOE between non-adjacent residues reveal a large population of folded structures. However, in trans DRM, 4 adjacent NOE Phe³/Gly⁴ can only be explained by an equilibrium between folded (ψ³ < 0) and extended (ψ³ > 0) conformations. Simulated annealing modeling gave about 60% (ψ³ < 0) and 40% (ψ³ > 0) of these conformer populations.

Trans DRM study and previous studies on the heptapeptide opioids, dermenkephalin (DREK) and deltorphin-I (δ selective), and DREK(1–4)-DRM(5–7) hybrid (μ selective), show in folded structures more backbone bending of the first 4 residues in the μ opioids than in the δ peptides. Also, the main difference between μ- and δ-opioid peptides is a large fraction of extended conformations in μ heptapeptides. Either bending of the N-terminus, or extension of the C-terminal part in μ-opioid heptapeptides prevent the head-to-tail interactions which allow δ-opioid peptides to bind selectively to the δ-opioid receptor.     

Opioid receptor selectivity of peptide models of beta-endorphin

Two peptides, designed to contain structural models of the proposed hydrophilic linker domain (residues 6-12) and amphiphilic alpha-helical domain (residues 13-29) in beta-endorphin, have been tested for their abilities to mimic the opioid receptor selectivity profile of the natural hormone. In competitive binding assays employing guinea-pig brain membranes, both peptides displayed a much higher affinity for mu- and delta-opioid receptors than for kappa opioid receptors. Relative to beta-endorphin, the peptide models were 2-3 times more potent in the mu and kappa receptor binding assays, and about equipotent in the delta receptor binding assay. In guinea-pig ileum assays, one peptide was equipotent to beta-endorphin and the other was twice as potent. Like beta-endorphin, their actions on this tissue were highly sensitive to naloxone antagonism, indicating that they were mediated by mu receptors and not kappa receptors. In view of the design of the two peptide models, and their minimal homology to the natural hormone, these results provide additional evidence in support to our proposal for the functional conformation of beta-endorphin.     

Biological activities of cyclic enkephalin pseudopeptides containing thioamides as amide bond replacements

Analogs of H-Tyr-cyclo(N epsilon-D-Lys-Gly-Phe-Leu) have been prepared which contain thioamides at the 3-4 position (monothio), 3-4 and 5-2 positions (dithio), and 2-3, 3-4, and 5-2 positions (trithio). These compounds have been tested for opioid activity in mu- and delta-receptor selective bio- and binding assays. As the number of sulfurs increased, the biological activities dropped on the guinea pig ileum and fluctuated modestly on the mouse vas deferens assay. Surprisingly, the compounds displayed increasing delta selectivity as the number of sulfurs increased. In the binding assay, the thioamide analogs tended to retain affinity toward the mu receptor. The mono- and dithio-analogs were more mu selective than the parent, while the trithio-analog was more delta selective. These results suggest that the subtle exchange of sulfur for oxygen can have a significant impact on receptor selectivity and affinity, and probably reflect the different conformation/structural requirements for binding vs. the biological transduction event.     

Delta opioidmimetic antagonists: prototypes for designing a new generation of ultraselective opioid peptides.

BACKGROUND: Tyr-Tic (1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid) and Tyr-Tic-Ala were the first peptides with delta opioid antagonist activity lacking Phe, considered essential for opioid activity based on the N-terminal tripeptide sequence (Tyr-D-Xaa-Phe) of amphibian skin opioids. Analogs were then designed to restrain the rotational flexibility of Tyr by the substitution of 2,6-dimethyl-L-tyrosine (Dmt). MATERIALS AND METHODS: Tyr and Dmt peptides were synthesized by solid phase and solution methods using Fmoc technology or condensing Boc-Dmt-OH or Boc-Tyr(But)-OH with H-L-Tic-OBut or H-D-Tic-OBut, respectively. Peptides were purified (> 99%) by HPLC and characteristics determined by 1H-NMR, FAB-MS, melting point, TLC, and amino acid analyses. RESULTS: H-Dmt-Tic-OH had high affinity (Ki delta = 0.022 nM) and extraordinary selectivity (Ki mu/Ki delta = 150,000); H-Dmt-Tic-Ala-OH had a Ki delta = 0.29 nM and delta selectivity = 20,000. Affinity and selectivity increased 8700- and 1000-fold relative to H-Tyr-Tic-OH, respectively. H-Dmt-Tic-OH and H-Dmt-Tic-NH2 fitted one-site receptor binding models (eta = 0.939-0.987), while H-Dmt-Tic-ol, H-Dmt-Tic-Ala-OH and H-Dmt-Tic-Ala-NH2 best fitted two-site models (eta = 0.708-0.801, F 18.9-26.0, p < 0.0001). Amidation increased mu affinity by 10- to 100-fold and acted synergistically with D-Tic2 to reverse selectivity (delta-->mu). Dmt-Tic di- and tripeptides exhibited delta antagonist bioactivity (Ke = 4-66 nM) with mouse vas deferens and lacked agonist mu activity (> 10 microM) in guinea-pig ileum preparations. Dmt-Tic analogs weakly interacted with kappa receptors in the 1 to > 20 microM range. CONCLUSIONS: Dmt-Tic opioidmimetic peptides represent a highly potent class of opioid peptide antagonists with greater potency than the nonopioid delta antagonist naltrindole and have potential application as clinical and therapeutic compounds.     

Cyclic, disulfide- and dithioether-containing opioid tetrapeptides: development of a ligand with high delta opioid receptor selectivity and affinity

Tetrapeptides of primary sequence Tyr-X-Phe-YNH2, where X is D-Cys or D-Pen (penicillamine) and where Y is D-Pen or L-Pen, were prepared and were cyclized via the side chain sulfurs of residues 2 and 4 to disulfide or dithioether-containing analogs. These peptides are related to previously reported penicillamine-containing pentapeptide enkephalin analogs but lack the central glycine residue of the latter and were designed to assess the effect of decreased ring size on opioid activity. Binding affinities of the tetrapeptides were determined to both mu and delta opioid receptors. Binding affinity and selectivity in the tetrapeptide series were observed to be highly dependent on primary sequence. For example, L-Pen4 analogs displayed low affinity and were nonselective, while the corresponding D-Pen4 diastereomers were of variable affinity and higher selectivity. Among the latter compounds were examples of potent analogs in which selectivity shifted from delta selective to mu selective as the ring size was increased. The relatively high binding affinity and delta receptor selectivity observed with one of the carboxamide terminal disulfide analogs led to the synthesis of the corresponding carboxylic acid terminal, Tyr-D-Cys-Phe-D-PenOH. This analog displayed delta receptor binding selectivity similar to that of the standard delta ligand, [D-Pen2,D-Pen5]enkephalin (DPDPE), and was found to have a 3.5-fold higher binding affinity than DPDPE. All the tetrapeptides were further evaluated in the isolated mouse vas deferens (mvd) assay and all displayed opioid agonist activity. In general, tetrapeptide potencies in the mouse vas deferens correlated well with binding affinities but were somewhat lower. Receptor selectivity in the mvd, assessed by examining the effect of opioid antagonists on the tetrapeptide concentration-effect curves, was similar to that determined in the binding studies.     

The biological consequences of replacing hydrophobic amino acids in deltorphin I with amphiphilic alpha-hydroxymethylamino acids.

New analogues of deltorphin I (DT I), in which the Phe residue in position 3, and the Val residue in position 5 or 6 are replaced with respective amphiphilic alpha-hydroxymethylamino acid residues (HmAA), were synthesized and tested for receptor affinity and selectivity to mu and delta opioid receptors. The analogue with (R)-HmPhe at position 3 lost receptor selectivity, as a result of a partial decrease of affinity to delta and a significant increase of affinity to mu receptors. In contrast, an analogue with (S)-HmPhe in the same position, was very potent and more specific to delta receptors than parent DT I. The analogue with (R)-HmVal at position 5 expressed higher delta affinity and selectivity than parent DT I. The analogue with other possible isomer (S)-HmVal was less selective for delta opioid receptors, as a result of decreasing affinity to delta and increasing affinity to mu receptors. The analogues with (R)- or (S)-HmVal in position 6 expressed equally low receptor affinity and selectivity. The data obtained support a previously proposed model of active conformation of deltorphins.     

Structural requirements for dermorphin opioid receptor binding

Structural features influencing binding activity of dermorphin to opioid receptors have been investigated in the rat brain through the synthesis and evaluation of binding affinity of a series of synthetic dermorphin analogs. Tritiated dermorphin was used as primary ligand. The single population of high affinity dermorphin binding sites present in the rat brain is clearly of an opioid nature since bound radiolabeled dermorphin was fully displaced with high affinity either by morphine or naloxone. Displacement of tritiated dermorphin by all alkaloid opiates or dermorphin related peptides tested was monophasic, consistent with simple competitive inhibition at a single population of binding sites. Dermorphin (Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2) was the most potent competitor in all experiments. The D-configuration of the amino acid residue in position 2 was found to be of crucial importance for binding. Replacement of D-Ala2 with L-Ala led to a deleterious effect, this analog being 1/5000th as potent as dermorphin in displacing bound tritiated dermorphin from its receptor. Shorter dermorphin homologs, dermorphin-(1-4)-NH2 and dermorphin-(1-3)-NH2, were found to be 20 and 40-fold less potent, respectively, than dermorphin. The C-terminal carboxamide function is of significant importance for manifestation of the full intrinsic binding potency of dermorphin. Deamidated dermorphin had 1/5th the potency of the parent peptide. This suggests that while the whole dermorphin sequence is required for the expression of the full intrinsic binding activity of the molecule, the N-terminal tripeptide is a key structure as it contains the features which allow receptor recognition.     

The aspartic acid in deltorphin I and dermenkephalin promotes targeting to delta-opioid receptor independently of receptor binding.

Recent studies on the highly potent and selective delta-opioid agonists demenkephalin (Tyr-D-Met-Phe-His-Leu-Met-Asp-NH2) and deltorphin I (Tyr-D-Ala-Phe-Asp-Val-Val-Gly-NH2) suggested that key structural features necessary for specific targetting to the delta-opioid receptor are located within the C-terminal halves of these naturally occurring heptapeptides. To investigate the contribution of aspartic acid 4 residue in deltorphin I and aspartic acid 7 residue in dermenkephalin to the delta-addressing ability of the C-terminal ends, fourteen analogs were synthesized and assessed for their ability to bind to mu and delta-opioid receptors in rat brain membrane homogenates. Results showed that i/ although the tetrapeptide C-terminus of dermenkephalin and deltorphin I differ in amino acid composition, they play a similar role in specifying correct addressing of these peptides to the delta-receptor, ii/ the negatively charged side chain of aspartic acid 4 residue in deltorphin I and aspartic acid 7 residue in dermenkephalin is not involved in binding contact at the delta-receptor site, nor in maintaining a delta-bioactive folding of the peptides, iii/ these side chains are, in contrast, functionally or structurally required to confer high delta-selectivity by preventing mu-site recognition and/or binding.     

Role of steric interactions in the delta opioid receptor selectivity of [D-Pen2, D-Pen5]enkephalin

In order to assess the individual effects of each of the 3-methyl groups in residue 2 of [D-Pen2, D-Pen5]enkephalin on binding affinity to mu and delta opioid receptors, (2S,3S)methylcysteine ((3S)Me-D-Cys) and (2S,3R)methylcysteine ((3R)Me-D-Cys) were synthesized and incorporated into the analogs, [(3S)Me-D-Cys2, D-Pen5] enkephalin and [(3R)Me-D-Cys2, D-Pen5]enkephalin. Of these analogs, [(3S)Me-D-Cys2, D-Pen5]enkephalin appears from 1H n.m.r. spectra to assume a conformation similar to those of [D-Pen2, D-Pen5]enkephalin and the less delta receptor-selective, but more potent, [D-Cys2, D-Pen5]enkephalin. Assessment of binding affinity to mu and delta receptors revealed that [(3S)Me-D-Cys2, D-Pen5]enkephalin exhibits delta receptor affinity intermediate between [D-Pen2, D-Pen5]enkephalin and [D-Cys2, D-Pen5]enkephalin while its mu receptor affinity is similar to that of [D-Cys2, D-Pen5]enkephalin. These results suggest that, for [D-Pen2, D-Pen5]enkephalin, adverse steric interactions between the D-Pen2 pro-R methyl group and the mu receptor binding site lead to the low mu receptor binding affinity observed for this analog. By contrast, both the pro-R and pro-S D-Pen2 methyl groups lead to minor steric interactions which contribute to the somewhat lower delta receptor affinity of this compound.     

Novel ligands for the opioid receptors: synthesis and structure-activity relationships among 5'-aryl and 5'-heteroaryl 17-cyclopropylmethyl-4,5 alpha-epoxypyrido[2',3':6,7]morphinans

A series of pyridomorphinans possessing an aryl (10a-s) or heteroaryl (11a-h) substituent at the 5'-position of the pyridine ring of 17-cyclopropylmethyl-4,5 alpha-epoxypyrido[2',3':6,7]morphinan was synthesized and evaluated for binding and functional activity at the opioid delta, mu, and kappa receptors. All of these pyridomorphinans bound with higher affinity at the delta site than at mu or kappa sites. The binding data on isomeric compounds revealed that there exists greater bulk tolerance for substituents placed at the o-position of the phenyl ring than at m- or p-positions. Among the ligands examined, the 2-chlorophenyl (10l), 2-nitrophenyl (10n), 2-pyridyl (11a), and 4-quinolinyl (11g) compounds bound to the delta receptor with subnanomolar affinity. Compound 10c with the p-tolyl substituent displayed the highest mu/delta selectivity (ratio=42) whereas compound 10l with the 2-chlorophenyl substituent displayed the highest kappa/delta selectivity (ratio=23). At 10 microM concentration, the in vitro functional activity determined using [(35)S]GTP-gamma-S binding assays showed that all of the compounds were antagonists devoid of any significant agonist activity at the delta, mu, and kappa receptors. Antagonist potency determinations of three selected ligands revealed that the p-tolyl compound 10c is a potent delta selective antagonist. In the [(35)S]GTP-gamma-S assays this compound had a functional antagonist K(i) value of 0.2, 4.52, and 7.62 nM at the delta, mu, and kappa receptors, respectively. In the smooth muscle assays 10c displayed delta antagonist potency with a K(e) value of 0.88 nM. As an antagonist, it was 70-fold more potent at the delta receptors in the MVD than at the mu receptors in the GPI. The in vitro delta antagonist profile of this pyridomorphinan 10c resembles that of the widely used delta selective antagonist ligand naltrindole.     

Synthesis and binding properties of specific photoaffinity ligands for mu and delta opioid receptor subtypes

We report the synthesis and binding properties of specific photoaffinity ligands for mu and delta opioid receptor subtypes. These ligands are derived from DAGO: Tyr-D-Ala-Gly-NMePhe-Gly-ol, a mu selective probe and DTLET: Tyr-D-Thr-Gly-Phe-Leu-Thr, a delta selective probe by modifying the Phe 4 residue. These modifications are: i) a nitro group on the para position of Phe ring as Phe(4 NO2) or Nip, ii) an azido group as Phe(4 N3) or AZ. Pharmacological responses on mouse vas deferens (delta sites) and guinea pig ileum (mu sites), as well as competition experiments with [3H] DAGO and [3H] DTLET on crude rat brain membranes have been performed. The nitro group on the phenyl ring of the Phe residue preserves the affinity and selectivity of each probe: NipDAGO for the mu sites, NipDTLET for the delta ones. However the nitro probes do not appear to be photoactivable by u.v. irradiation. Likewise, azidation of the phenyl ring of the Phe residue does not change the receptor selectivity of each probe, but AZDAGO has less affinity than its parent molecule DAGO, while AZDTLET has more affinity than DTLET. These compounds are photoactivable and provide an efficient tool to characterize and isolate the different receptor subtypes, especially the delta site.