Substitution on the Phe3 aromatic ring in cyclic delta opioid receptor-selective dermorphin/deltorphin tetrapeptide analogues: electronic and lipophilic requirements for receptor affinity.

In an effort to explore structural features affecting receptor recognition in a series of conformationally restricted tetrapeptides related to the cyclic, delta opioid receptor-selective analogue, [formula: see text] electronic, lipophilic, and steric effects at the Phe3 residue were assessed by substitution at different positions of the side-chain aromatic ring by halogens, alkyl, hydroxyl, and nitro groups. Effects on opioid receptor binding affinity and selectivity were determined. The results, which are generally consistent with reports of analogous modifications in linear and cyclic pentapeptide enkephalins, indicate that steric, lipophilic, and electronic properties are all important determinants of delta opioid receptor recognition. Specifically, modifications which increase lipophilicity or exert electron-withdrawing effects on the aromatic ring enhance binding affinity, while hydrophilic, bulky, or electron-releasing modifications are detrimental. These observations are in excellent agreement with quantitative structure-activity relationship (QSAR) results reported for Phe4 modifications in linear opioid pentapeptide enkephalin analogues, suggesting that the Phe3 tetrapeptide side chain and the Phe4 pentapeptide side chain interact with the same delta receptor binding subsite.     

Opioid receptor affinity and selectivity effects of second residue and carboxy terminal residue variation in a cyclic disulfide-containing opioid tetrapeptide

The previously described cyclic, delta opioid receptor-selective tetrapeptide H-Tyr-d -Cys-Phe-d -Pen-OH, where Pen, penicillamine, is β,β-dimethylcysteine, was modified at residues 2 and 4 by varying combinations of d - and l -Cys and d - and l -Pen, and effects on mu and delta opioid receptor binding affinities and on potency in the mouse vas deferens (MVD) smooth muscle assay were evaluated. A comparison was drawn between consequences of alterations in this series of analogs and those of analogous modifications in the related cyclic pentapeptide series which includes the highly delta receptor-selective [d -Pen²,d -Pen⁵]enke-phalin, DPDPE. Unlike effects observed in the cyclic pentapeptide series, the mu receptor binding affinities of the cyclic tetrapeptides are not dramatically influenced by substitution of Pen for Cys at residue 2. Conversely, while binding of the pentapeptides is only slightly affected by alteration of the chirality of the carboxy-terminal residue, modification of stereochemistry at the carboxy terminus in the tetrapeptides critically alters binding behavior at both mu and delta sites. In contrast with the pentapeptide series, the tetrapeptides appear to be highly dependent upon primary sequence for binding and activity, as only the lead compound binds with high affinity to the delta site. Results suggest that the less flexible cyclic tetrapeptides, lacking the Gly³ residue, display more stringent structural requirements for binding and activity than do the corresponding cyclic pentapeptides.     

Modification of the Phe3 aromatic moiety in delta receptor-selective dermorphin/deltorphin-related tetrapeptides Effects on opioid receptor binding

The previously described cyclic delta opioid receptor-selective tetrapeptide H-Tyr-d -Cys-Phe-d -Pen-OH (JOM-13) was modified at residue 3 by incorporation of both natural and unnatural amino acids with varying steric, electronic, and lipophilic properties. Effects on mu and delta opioid receptor binding affinities were evaluated by testing the compounds for displacement of radiolabeled receptor-selective ligands in a guinea pig brain receptor binding assay. Results obtained with the bulky aromatic 1-Nal³ and 2-Nal³ substitutions suggest that the shape of the receptor subsite with which the side chain of the internal aromatic residue interacts differs for delta and mu receptors. This subsite of either receptor can accommodate the transverse steric bulk of the 1-Nal³ side chain but only the delta receptor can readily accept the more elongated 2-Nal³ side chain. Several analogs with pi-excessive heteroaromatic side chains in residue 3 were examined. In general, these analogs display diminished binding to mu and delta receptors, consistent with previous findings for analogs with residue 3 substitutions of modified electronic character. Several analogs with alkyl side chains in residue 3 were also examined. While delta receptor binding affinity is severely diminished with Val³, Ile³, and Leu³ substitutions, Cha³ substitution is very well tolerated, indicating that, contrary to the widely held belief, an aromatic side chain in this portion of the ligand is not required for delta receptor binding. Where possible, comparison of results in this delta-selective tetrapeptide series with those reported for analogous modification in the cyclic delta-selective pentapeptide [d -Pen², d -Pen⁵]enkephalin (DPDPE) and linear pentapeptide enkephalins reveals similar trends.     

D-Pen2,D-Pen5]enkephalin analogues with increased affinity and selectivity for delta opioid receptors

The conformationally restricted, cyclic disulfide-containing enkephalin analogue [D-Pen2,D-Pen5]enkephalin (DPDPE) was modified by halogenation (F, Cl, Br, I) of the phenylalanine-4 residue in the para position. The potency and selectivity of these analogues for the delta opioid receptor was greater than that of the parent peptide. The analogues possessed greater potency and affinity for the delta receptors than DPDPE in the mouse vas deferens assay and in radioreceptor assays (against [3H]DPDPE), respectively. [p-ClPhe4]DPDPE was the most selective in the radioligand binding assays (IC50(mu)/IC50(delta) = 574), being about 5-fold more delta opioid receptor selective than DPDPE in this assay, whereas [p-IPhe4]DPDPE was the most selective in the classical bioassay systems using the mouse vas deferens and guinea pig ileum assays (IC50(GPI)/IC50(MVD) = 17,374), making it nearly 9-fold more selective than DPDPE in direct comparisons using the same assay conditions.     

Topographically designed analogues of [D-Pen,D-Pen5]enkephalin.

The conformationally restricted, cyclic disulfide-containing delta opioid receptor selective enkephalin analogue [D-Pen2,D-Pen5]enkephalin (1, DPDPE) was systematically modified topographically by addition of a methyl group at either the pro-S or pro-R position of the beta carbon of an L-Phe4 or D-Phe4 residue to give [(2S,3S)-beta-MePhe4]DPDPE (2), [(2R,3R)-beta-MePhe4]DPDPE (3), [(2S,3R)-beta-MePhe4]DPDPE (4), and [(2R,3S)-beta-MePhe4]DPDPE (5). The four corresponding isomers were prepared in which the beta-methylphenylalanine residue was p-nitro substituted, that is with a beta-methyl-p-nitrophenylalanine (beta-Me-p-NO2Phe) residue, to give [(2S,3S)-beta-Me-p-NO2Phe4]DPDPE (6), [(2R,3R)-beta-Me-p-NO2Phe4]DPDPE (7), [(2S,3R)-beta-Me-p-NO2Phe4] DPDPE (8), and [(2R,3S)-beta-Me-p-NO2Phe4]DPDPE (9), respectively. The potency and selectivity (delta vs mu opioid receptor) were evaluated by radioreceptor binding assays in the rat brain using [3H]CTOP (mu ligand) and [3H]DPDPE (delta ligand) and by bioassay with mouse vas deferens (MVD, delta receptor assay) and guinea pig ileum (GPI, mu receptor assay). The eight analogues of DPDPE showed highly variable binding and bioassay activities particularly at the delta opioid receptor (4 orders of magnitude), but also at the mu opioid receptor, which led to large differences (3 orders of magnitude) in receptor selectivity. For example, [(2S,3S)-beta-MePhe4]DPDPE (2) is 1800-fold selective in binding to the delta vs mu receptor, making it one of the most selective delta opioid receptor ligands in the enkephalin series as assessed by the rat brain binding assay, whereas the corresponding (2R,3R)-beta-Me-p-NO2Phe-containing analogue 9 is only 4.5-fold selective (nonselective) in this same assay. On the other hand, in the bioassay systems, [(2S,3S)-beta-Me-p-NO2Phe4]DPDPE (5) is more potent than DPDPE and 8800-fold selective for the MVD (delta receptor) vs the GPI (mu receptor), making it the most highly selective ligand in this series for the delta opioid receptor on the basis of these bioassays. In these assay systems, the (2R,3S)-beta-MePhe4-containing analogue 5 had very weak potency and virtually no receptor selectivity (4.4-fold). These results demonstrate that topographical modification alone in a conformationally restricted peptide ligand can significantly modulate both potency and receptor selectivity of peptide ligands that have multiple sites of biological activity and suggest that this approach may have general application to peptide ligand design.     

2',6'-dimethylphenylalanine (Dmp) can mimic the N-terminal Tyr in opioid peptides

Substitution of 2',6'-dimethyltyrosine (Dmt) for the N-terminal Tyr in opioid peptides has recently been shown to be a promising tool for improving opioid receptor affinity and biological activity. We have also demonstrated that another unnatural amino acid, 2',6'-dimethylphenylalanine (Dmp), is not only an excellent substitute for Phe at position 3 but also can mimic the aromatic N-terminal Tyr residue in a micro opioid receptor-selective dermorphin analogue (YRFB: Tyr-D-Arg-Phe-betaAla-NH(2)). To further evaluate the value of Dmp in opioid peptides, we investigated Dmp(1)-substituted analogues of the delta receptor ligands, deltorphin II (DLT: Tyr-D-Ala-Phe-Glu-Val-Val-Gly-NH(2)) and enkephalin (ENK: Tyr-Gly-Gly-Phe-Leu). In the receptor binding assay, both [Dmp(1)]DLT and [Dmp(1)]ENK bound to the delta-receptor with high affinity and selectivity, and were nearly as effective as the parent peptides. The potency of the Dmp(1)-peptides on the MVD and GPI assays correlated well with the receptor binding affinity data. These results are in contrast to the tendency of corresponding Dmt(1)-analogues to have poor receptor selectivity. Taken together with the results with YRFB, we conclude that the Dmp(1)-peptide is superior to the corresponding Dmt(1)-peptide in its receptor selectivity. [Dmp(1)]DLT and [Dmp(1)]YRFB may serve as pharmacological tools for the studies of ligand recognition and opioid receptor signal transduction.     

Conformationally restricted deltorphin analogues.

Conformationally restricted deltorphin analogues were synthesized either through incorporation of cyclic phenylalanine analogues in position 2 or 3 of the peptide sequence or through various side chain-to-side chain cyclizations. Compounds were tested in mu-, delta-, and kappa-receptor selective binding assays and in the guinea pig ileum (GPI) and mouse vas deferens (MVD) bioassays. Replacement of Phe3 in [D-Ala2]deltorphin I with 2-aminoindan-2-carboxylic acid (Aic) or L- or D-2-aminotetralin-2-carboxylic acid (Atc) resulted in agonist compounds which retained the high delta receptor selectivity of the parent peptide. Substitution of a tetrahydroisoquinoline-3-carboxylic acid (Tic) residue in the 2-position of [D-Ala2]deltorphin I and of [Phe4,Nle6]deltorphin produced a partial delta agonist, H-Tyr-Tic-Phe-Asp-Val-Val-Gly-NH2, and a pure delta antagonist, H-Tyr-Tic-Phe-Phe-Leu-Nle-Asp-NH2, respectively. The latter antagonist displayed high delta selectivity (Ki mu/Ki delta = 502) and was a potent antagonist against selective delta agonists in the MVD assay (Ke congruent to 10 nM). Various [D-Ala2]-deltorphin I analogues cyclized between the side chains of Orn (or Lys) and Asp (or Glu) residues substituted in positions 2 and 4, 4 and 7, and 2 and 7 were essentially nonselective. Comparison with corresponding N-terminal tetrapeptide analogues revealed that the C-terminal tripeptide segment in the deltorphin heptapeptides made a crucial contribution to delta affinity and delta selectivity in the case of the agonist peptides but not in the case of the antagonist.     

Species differences in mu- and delta-opioid receptors.

The mu opioid receptor ligand [D-Ala2, NMePhe4, Gly-ol5]enkephalin (DAGO) and delta opioid receptor ligand [D-Pen2,D-Pen5]enkephalin (DPDPE) show similar specificity in competition binding studies in whole brain homogenate in rat and mouse. However, in saturation studies, the density and affinity of DPDPE binding sites were substantially greater in the mouse. There was no difference between the mouse and rat in the density and affinity of DAGO sites. Results from dose-response studies for analgesia using the same ligands administered i.c.v. in both species paralleled the binding studies. DAGO was approximately 2 times more potent in the mouse compared to the rat; while DPDPE was more than 15 times more potent in the mouse. Thus, binding capacity and affinity differences appear to be related to the functional potency of the mu and delta ligands in the two species. These results suggest that the difference in potency of DPDPE between rat and mouse is related to the differences in brain delta opioid receptors.     

Ring substituted and other conformationally constrained tyrosine analogues of [D-Pen2,D-Pen5]enkephalin with delta opioid receptor selectivity.

The conformationally restricted, cyclic disulfide-containing delta opioid receptor selective enkephalin analogue [D-Pen2,D-Pen5] enkephalin (DPDPE) was modified by 2' (CH3) and 3' (I, OCH3, NO2, NH2) ring substitutions and by beta-methyl conformationally constrained beta-methyltyrosine derivatives in the 1 position. The potency and selectivity of these analogues were evaluated by bioassay in the mouse vas deference (MVD, delta receptor assay) and guinea pig ileum (GPI, mu receptor assay) assays and by radioreceptor binding assays in the rat brain using [3H]CTOP (mu ligand) and [3H][p-ClPhe4]DPDPE (delta ligand). The analogues showed highly variable potencies in the binding assays and in the bioassays. Aromatic ring substituents with positive Hammett constants had decreased potency, while substituents with negative Hammett constraints has increased potency for the opioid receptor. The most potent and most selective compound based on the binding was [2'-MeTyr1]DPDPE (IC50 = 0.89 nM and selectivity ratio 1310 in the binding assays). The 6-hydroxy-2-aminotetralin-2-carboxylic acid-containing analogue, [Hat1]DPDPE, also was highly potent and selective in both assays, demonstrating that significant modifications of tyrosine in enkephalins are possible with maintenance of high potency and delta opioid receptor selectivity. Of the beta-methyl-substituted Tyr1 analogues, [(2S,3R)-beta-MeTyr1]DPDPE was the most potent and the delta receptor selective. The results with substitution of beta-MeTyr or Hat instead of Tyr also demonstrate that topographical modification in a conformationally restricted ligand can significantly modulate both potency and receptor selectivity of peptide ligands that have multiple sites of biological activity.     

Receptor binding and biological activity of bivalent enkephalins

Two series of dimeric enkephalin analogues were assayed for opioid activity in two isolated smooth muscle preparations: the guinea pig ileum (GPI) and the mouse vas deferens (MVD). Dimers have the general structure: X-(CH2)n-X, where X is H-Tyr-D-Ala-Gly-Phe-Leu-NH-(n = 0, 2, 4, 6, 8, 10, 12), for the first series of dimeric pentapeptide enkephalins (DPEn), and H-Tyr-D-Ala-Gly-Phe-NH-(n = 2, 4, 6, 8, 12), for the series of dimeric tetrapeptide enkephalins (DTEn). Comparison of biological activities with binding affinities revealed that: (1) the DPE series with n = 2-8 showed increased potency in the MVD assay relative to monomeric [D-Ala2, Leu5]enkephalinamide (DALEA); (2) there was an associated increase affinity for the delta receptor of rat brain or neuroblastoma-glioma hybrid cells. (however, the relative potencies were higher in the MVD assay then predicted on the basis of binding affinities); (3) the DTE series also showed an increase in delta receptor affinities and MVD potencies relative to DALEA, for n = 2-12; (4) for the DTE series, the increase in MVD activities was less than that expected on the basis of delta binding affinity; (5) for both the DPE and DTE series, activities in the GPI assay and mu-receptor affinities were highly correlated: as the length of the methylene bridge increased from 2 to 12, there was a progressive loss of activity in both assays, with a similar pattern for DPE and DTE. Two selected dimers and their corresponding monomers were also assayed for antinociceptive activity in vivo: results were consistent with GPI and mu-binding but not with MVD and delta-binding. Two alkylamide analogs of penta- and tetrapeptide monomers, representing the monomer with the attached spacer of the most active dimers, were also assayed in biological and binding assays. Comparison of these compounds with the corresponding dimers suggest that the changes in activities and selectivities induced by dimerization are not a spurious effect of the presence of an akylamide derivative of the carboxy terminal of enkephalin but rather may represent a specific effect due to the bivalent nature of the ligands.     

Structural requirements for delta opioid receptor binding

Structural features influencing opioid activity of enkephalin analogs were investigated through the synthesis and evaluation of opioid receptor binding affinities of a series of cyclic dithioether-containing analogs and structurally related linear analogs of the cyclic, disulfide-containing peptides, [D-Pen2, D-Pen5]enkephalin and [D-Pen2, L-Pen5]enkephalin, where Pen (penicillamine) is beta, beta-dimethylcysteine. The major effect of increasing the ring size of the cyclic moiety from disulfide to dithioether analogs was a large decrease in delta opioid receptor binding affinity which suggests that relatively compact conformations of the peptide ligand are necessary for optimal binding to this receptor. The effect of bulky, hydrophobic residues at position 2 in the peptide chain was evaluated by preparing the linear analogs, [D-t-Leu2, D-t-Leu5]enkephalin (t-Leu, 2-amino-3,3-dimethylbutanoic acid) and [D-Abu2, D-t-Leu5]enkephalin (Abu, 2-aminobutanoic acid). The former analog was found to be 36- and 450-fold less potent at delta and mu receptor sites, respectively, than was the latter, suggesting that bulky side chain substituents in position 2 of enkephalin analogs lead to a deleterious steric interaction at delta and particularly at mu receptors.     

Stereospecificity of amino acid side chains in deltorphin defines binding to opioid receptors.

A series of individual D-amino acid replacement analogues of deltorphin A, several of which were in combination with a His4 deletion, were used to probe alterations of side-chain orientation on peptide binding parameters with rat brain opioid receptors. Peptides with D-amino acids in residues 1, 3, and 5 exhibited diminished affinities primarily for delta receptors (88-1200-fold) with selectivity decreasing by factors of 13-64-fold relative to deltorphin A (Ki delta = 0.45 nM; Ki mu/Ki delta = 764): the aromatic side chains Tyr1 and Phe3, which lie in the N-terminal "message" domain and the aryl side chain of Leu5 in the C-terminal "address" domain, appear to play essential roles in conferring high delta affinity and selectivity. Although D-His4 only decreased delta affinity by 6-fold and selectivity by a factor of 4, His appears to be involved as an integral component of both domains: [des-His4]deltorphin A and [des-His4] analogues containing consecutive D-amino acid replacements in the remaining residues exhibited weak binding to delta receptors and poor delta selectivity. Substitution of D-Met2 in deltorphin A by D-Ala or D-Nle decreased delta selectivities 3-6-fold through an elevation in mu affinities; however, the converse replacement, D-Met for D-Ala2 in deltorphin B, diminished beta selectivity by an order of magnitude only through the loss in delta affinity. The data show that the high delta affinity and selectivity of deltorphins correlate with and require a strict stereospecificity of the amino acid residue side chains.     

Systemic analgesic activity and delta-opioid selectivity in [2,6-dimethyl-Tyr1,D-Pen2,D-Pen5]enkephalin.

The cyclic peptide [2,6-dimethyl-Tyr1,D-Pen2,D-Pen5]enkephalin (2) was synthesized by solid-phase techniques and contains the optically pure unnatural amino acid 2,6-dimethyltyrosine (DMT) as a replacement for the Tyr1 residue of [D-Pen2,D-Pen5]enkephalin (DPDPE, 1). This structural modification resulted in a 10-fold increase in the potency of 2 at the delta opioid receptor and a 35-fold increase in potency at the mu receptor while substantial delta receptor selectivity was maintained. In addition, 2 was 86-fold more effective than 1 at inhibiting electrically stimulated contractions of the mouse vas deferens. In the hot plate test, 2 was 7-fold more potent than 1 after intracerebroventricular administration in the mouse. While 1 was inactive following systemic administration of doses as high as 30 mg/kg, subcutaneous administration of 2 significantly inhibited writhing with an ED50 of 2.6 mg/kg. These results demonstrate that the potency and systemic activity of DPDPE are significantly increased by replacement of Tyr1 with DMT.     

Stress prevents the chronic ethanol-induced delta opiod receptor supersensitivity in the rat brain

The effects of ethanol administration on binding characteristics of the highly selective mu and delta opioid receptor agonists 8H-[D-Ala2-MePhe4-Gly5-ol]enkephalin (3H-DAGO) and 3H-[D-Pen2, D-Pen5] enkephalin (3H-DPDPE), respectively, were investigated in the rat brain. Chronic but not acute ethanol administration profoundly increased affinity of 3H-DPDPE without changing the number of delta receptors. Stress, applied before each ethanol administration, prevents the above changes. On the other hand, chronic treatment with ethanol did not affect the binding characteristics of 3H-DAGO. These results suggest particular sensitivity of the delta opioid receptor to chronic ethanol administration. Furthermore, a possible involvement of endogenous opioid peptide systems in the enhancement of delta opioid receptor sensitivity is postulated.     

Synthesis,biology, NMR and conformation studies of the topographically constrained δ‐opioid selective peptide analogs of [β‐iPrPhe3]deltorphin I

Abstract: Replacement of Phe³ in the endogenous δ‐opioid selective peptide deltorphin I with four optically pure stereoisomers of the topographically constrained, highly hydrophobic novel amino acid β‐isopropylphenylalanine (β‐iPrPhe) produced four pharmacologically different deltorphin I peptidomimetics. Radiolabeled ligand‐binding assays and in vitro biological evaluation indicate that the stereoconfiguration of the iPrPhe residue plays a crucial role in determining the binding affinity, bioactivity and selectivity of [β‐iPrPhe³]deltorphin I analogs: a (2S,3R) configuration of the iPrPhe³ residue in [β‐iPrPhe³]deltorphin I provided the most desirable biological properties with binding affinity (IC₅₀ = 2 n m ), bioassay potency (IC₅₀ = 1.23 n m in MVD assay) and exceptional selectivity for the δ‐opioid receptor over the µ‐opioid receptor (30 000). Further conformational studies based on two‐dimensional NMR and computer‐assisted molecular modeling suggested a model for the possible bioactive conformation in which the Tyr¹ and (2S,3R)‐β‐iPrPhe³ residues adopt trans side‐chain conformations, and the linear peptide backbone favors a distorted β‐turn conformation.     

Structure-activity relationships of bifunctional peptides based on overlapping pharmacophores at opioid and cholecystokinin receptors

Cholecystokinin (CCK) has been identified as a pronociceptive endogenous peptide which also possesses antiopioid actions. CCK may be upregulated in conditions of chronic pain or during sustained morphine administration resulting in attenuation of opioid-mediated pain relief. These complex interactions between opioids and endogenous CCK receptor systems have suggested the need for a new paradigm in drug design for some states of chronic pain. In these circumstances the rational design of potential drugs for the treatment of these conditions must be based on one ligand for multiple targets. We have designed a single peptide which can interact with delta and mu opioid receptors as agonists and with CCK receptors as antagonists. The ligands were designed based on a model of overlapping pharmacophores of opioid and CCK peptide ligands, which incorporates opioid pharmacophores at the N-terminal and CCK tetrapeptide pharmacophores at the C-terminal of the designed ligands. We measured binding and activities of our bifunctional peptides at opioid and CCK receptors. Compound 11 (Tyr-d-Ala-Gly-d-Trp-NMeNle-Asp-Phe-NH(2)) demonstrated opioid agonist properties at delta and mu receptors (IC(50) = 63 +/- 27 nM and 150 +/- 65 nM, respectively in MVD and GPI tissue assays) and high binding affinity at CCK-1 and CCK-2 receptors (K(i) = 320 and 1.5 nM, respectively). Compound 9 (Tyr-d-Nle-Gly-Trp-Nle-Asp-Phe-NH(2)) displayed potent agonist activity at delta and mu receptors (IC(50) = 23 +/-10 nM and 210 +/- 52 nM, respectively in MVD and GPI tissue assays), with a balanced binding affinity for CCK-1 and CCK-2 receptors (K(i) = 9.6 and 15 nM, respectively). These results provide evidence supporting the concept that opioid and CCK receptors have overlapping pharmacophores required for binding affinity and biological activity and that designing overlapping pharmacophores of two peptides into a single peptide is a valid drug design approach.     

Effect of aromatic amino acid substitutions in the 3-position of cyclic β-casomorphin analogues on μ-opioid agonist/δ-opioid antagonist properties*

The β-casomorphin-5 analog H-Tyr-c[-D-Orn-2-Nal-D-Pro-Gly-] (2-Nal = 2-naphthylalanine) was the first reported cyclic opioid peptide with mixed μ agonist/δ antagonist properties [R. Schmidt et al. (1994) J. Med. Chem. 37 , 1136-1144]. The 2-Na1³ residue in this peptide was replaced with benzothienylalanine (Bta) (3), His(Bz1) (4), Tyr(Bz1) (5), 4′-benzoylphenylalanine (Bpa) (6), 4′-benzylphenylalanine (Bzp) (7), thyrnine (Thy) (8), thyroxine (Thx) (9), 4′-biphenylalanine (Bip) (10), 4′-biphenylglycine (Bpg) (12) and 3,3-diphenylalanine (Dip) (14), and the in vitro opioid activity profiles of the resulting compounds were determined in μ and δ receptor-representative binding assays and bioassays. Analogues 3, 12 and 14 were full agonists in the μ receptor-representative guinea-pig ileum (GPI) assay and also were agonists in the δ receptor-representative mouse vas deferens (MVD) assay. The agonist effects of the latter compounds in the MVD assay were antagonized by the highly selective δ antagonist H-Tyr-Tic-Phe-Phe-OH (TIPP), indicating that they were triggered by δ receptor activation. The Bzp³- and Bip³-containing peptides 7 and 10 turned out to be μ antagonists against the μ selective agonist H-Tyr-D-Ala-Phe-Phe-NH₂, in the GPI assay. The other analogues were weak partial μ agonists which displayed remarkably decreased μ receptor affinity as compared to parent peptide 1. Compounds 4-10 were found to be δ antagonists in the MVD assay. Analogues 4 and 9 exhibited δ antagonist potency similar to that of parent peptide 1, while compounds 5-8 and 10 showed 3-12-fold higher δ antagonist potency against DPDPE and deltorphin I and, in most cases, increased δ receptor affinity. These results indicate that the & delta; receptor tolerates bulky aromatic side chains in the 3-position of cyclic β-casomorphin analogs with either δ agonist or δ antagonist properties. However, these compounds displayed drastically reduced μ receptor affinity in nearly all cases. © Munksgaard 1996.     

Synthesis, opioid receptor binding, and biological activities of naltrexone-derived pyrido- and pyrimidomorphinans.

A series of pyrido- and pyrimidomorphinans (6a-h and 7a-g) were synthesized from naltrexone and evaluated for binding and biological activity at the opioid receptors. The unsubstituted pyridine 6a displayed high affinities at opioid delta, mu, and kappa receptors with K(i) values of 0.78, 1.5, and 8.8 nM, respectively. Compound 6a was devoid of agonist activity in the mouse vas deferens (MVD) and guinea pig ileum (GPI) preparations but was found to display moderate to weak antagonist activity in the MVD and GPI with K(e) values of 37 and 164 nM, respectively. The pyrimidomorphinans in general displayed lower binding potencies and delta receptor binding selectivities than their pyridine counterparts. Incorporation of aryl groups as putative delta address mimics on the pyrido- and pyrimidomorphinan framework gave ligands with significant differences in binding affinity and intrinsic activity. Attachment of a phenyl group at the 4'-position of 6a or the equivalent 6'-position of 7a led to dramatic reduction in binding potencies at all the three opioid receptors, indicating the existence of a somewhat similar steric constraint at the ligand binding sites of delta, mu, and kappa receptors. In contrast, the introduction of a phenyl group at the 5'-position of 6a did not cause any reduction in the binding affinity at the delta receptor. In comparison to the unsubstituted pyridine 6a, the 5'-phenylpyridine 6c showed improvements in mu/delta and kappa/delta binding selectivity ratios as well as in the delta antagonist potency in the MVD. Interestingly, introduction of a chlorine atom at the para position of the pendant 5'-phenyl group of 6c not only provided further improvements in delta antagonist potency in the MVD but also shifted the intrinsic activity profile of 6c from an antagonist to that of a mu agonist in the GPI. Compound 6d thus possesses the characteristics of a nonpeptide mu agonist/delta antagonist ligand with high affinity at the delta receptor (K(i) = 2.2 nM), high antagonist potency in the MVD (K(e) = 0.66 nM), and moderate agonist potency in the GPI (IC(50) = 163 nM). Antinociceptive evaluations in mice showed that intracerebroventricular (icv) injections of 6d produced a partial agonist effect in the 55 degrees C tail-flick assay and a full agonist effect in the acetic acid writhing assay (A(50) = 7.5 nmol). No signs of overt toxicity were observed with this compound in the dose ranges tested. Moreover, repeated icv injections of an A(90) dose did not induce any significant development of antinociceptive tolerance in the acetic acid writhing assay. The potent delta antagonist component of this mixed mu agonist/delta antagonist may be responsible for the diminished propensity to produce tolerance that this compound displays.     

Investigation of the structural parameters involved in the mu and delta opioid receptor discrimination of linear enkephalin-related peptides

The previous rules proposed for selective recognition of mu and delta opioid receptors by modified enkephalins were investigated through an extensive structure-activity study. Thus, modifications of the sequence of TRIMU 4 (Tyr-D-Ala-Gly-NHCH(CH3)CH2CH(CH3)2, a peptide that exhibits mu selectivity close to that of DAGO (Try-D-Ala-Gly-N(Me)Phe-Gly.ol), were performed for two positions, 2 and 4, critical for mu recognition. The drastic loss of potency following introduction of L-Ala or Aib in position 2 emphasizes the importance of the stereochemistry and the steric size of the X2 amino acid for optimal mu binding. The enhancement of the intrinsic flexibility of the C-terminal alkyl chain of TRIMU 4 through removal of a methyl group leads to TRIMU 5 (Tyr-D-Ala-Gly-NHCH2CH2CH(CH3)2), a peptide with a mu selectivity similar to that of DAGO. In contrast, introduction of an O-tert-butyl Ser2 residue increases affinity for delta receptors. In the hexapeptide series derived from DSLET (Tyr-D-Ser-Gly-Phe-Leu-Thr), a D-Thr2 moiety was shown to be very efficient in improving delta recognition and delta selectivity appeared also to be modulated by the nature of the sixth residue. The potencies of the 24 peptides studied to inhibit the electrically evoked contractions of the GPI or MVD are relatively well correlated with their affinities for brain mu or delta receptors labeled with [3H]DAGO or [3H]DSLET, respectively. Moreover, the analgesic potency (hot plate test) of the peptides is related to their affinity for rat brain mu receptors. The wide range of receptor affinities exhibited by the compounds reported here could be useful to study the physiological role of mu and delta receptors.     

Binding of growth hormone-releasing hormones and enkephalin-derived growth hormone-releasing peptides to mu and delta opioid receptors in forebrain of rat

The purpose of this study was to compare the binding potency to opioid receptors of met-enkephalin-derived, hypophysiotrophic peptides with their reported growth hormone (GH)-releasing strengths in vitro and further, to determine the relative selectivity of each peptide for mu and delta opioid binding sites in the forebrain of the rat. A series of (GH)-releasing pentapeptides and hexapeptides (GHRP's), as well as rat (rGHRH) and human (hGHRH) growth hormone-releasing hormones were tested for preferential binding to specific opioid receptors. The site selectivity of each peptide was determined by its ability to compete for binding with synthetic ligands for mu (Tyr-D-Ala-Gly-MePhe-Gly-ol; DAGO) and delta ([D-Pen2,5]-enkephalin; DPDPE) opioid receptors. The various peptides differed in their selectivities for the two opioid receptors in that most of the GHRP's were mu-selective, while the naturally occurring GHRH's were delta-selective. Amidation of the C-terminal decreased delta selectivity. Besides affecting selectivity for the site, structural changes that enhanced GH-release by enkephalin-derived peptides also decreased their potency to compete for opioid binding sites. For example, dose-response curves for His-D-Trp-Ala-Trp-D-Phe-Lys-NH2 (SK&F 110679) inhibition of the binding of DAGO and DPDPE yielded IC50's of 6 and 20 microM, respectively. In contrast, Tyr-D-Trp-Gly-Phe-Met-NH2 (BI360), which is 1 X 10(3) times weaker than SK&F 110679 in releasing GH, had IC50's of 0.1 microM and 0.08 microM for inhibition of the binding of DAGO and DPDPE, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)