Cystamine-enkephalin dimer

A cystamine-enkephalin dimer, containing two molecules of [D-Ala², Leu⁵] enkephalin cross-linked at the COOH-terminal leucine residue with cystamine, (NH₂-CH₂-CH₂-S-)₂, has been synthesized in order to examine directly the dimerization effect of an enkephalin molecule on the opiate receptor interactions. In a comparison of potencies against [³H]-[D-Ala²,D-Leu⁵]enkephalin (³H-DADLE) and [³H]-[D-Ala²,MePhe⁴,Gly-ol⁵]enkephalin (³H-DAGO) as delta and mu tracers, respectively, enkephalin dimer showed a very high affinity, especially for the delta opiate receptors. Dimer was almost threefold more potent than DADLE, which is one of the most utilized delta ligand to date. When the binding affinity of cystamine-dimer was compared with that of its reduced thiol-monomer, namely [D-Ala²,Leu⁵, cysteamine⁶]enkephalin, the increment in affinity was four to fivefold for both delta and mu receptors. The results strongly indicate that the dimeric enkephalin is more potent presumably due to the simultaneous interaction with the two binding sites of the opiate receptors.     

Synthesis and receptor binding affinity of both E-and Z-dehydro-phenylaline4 enkephalins*

The dehydrophenylalanine⁴-enkephalin having the E-configuration (Δ^EPhe; phenyl and C = O, cis) was prepared by photoisomerization of the Z-isomer with 3100 Å light, followed by reversed-phase HPLC separation of the resulting mixture of the Z- and E-isomers. In the radioligand receptor binding assays, the E-isomer of [D-Ala², ΔPhe⁴, Leu⁵]enkephalin exhibited an extremely diminished affinity as compared with the Z-isomer, namely 150–260-fold loss of affinity for the delta and mu opiate receptors. The results indicate that the interrelationship of the Tyr¹ and Phe⁴ residues in the enkephalin molecule seems to be of great importance in receptor recognition.     

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.     

Synthesis and evaluation of N,N-dialkyl enkephalin-based affinity labels for delta opioid receptors

To develop affinity labels for delta opioid receptors based on peptide antagonists, the Phe(4) residues of N,N-dibenzylleucine enkephalin and N,N-diallyl[Aib(2),Aib(3)]leucine enkephalin (ICI-174, 864) were substituted with either Phe(p-NCS) or Phe(p-NHCOCH(2)Br). A general synthetic method was developed for the conversion of small peptide substrates into potential affinity labels. The target peptides were synthesized using Phe(p-NH(2)) and a Boc/Fmoc orthogonal protection strategy which allowed for late functional group conversion of a p-amine group in the peptides to the desired affinity labeling moieties. A key step in the synthesis was the selective deprotection of a Boc group in the presence of a tert-butyl ester using trimethylsilyl trifluoromethanesulfonate (TMS-OTf). The target peptides were evaluated in radioligand binding experiments in Chinese hamster ovary (CHO) cells expressing delta or mu opioid receptors. The delta receptor affinities of the N, N-dibenzylleucine enkephalin analogues were 2.5-10-fold higher than those for the corresponding ICI-174,864 analogues. In general, substitution at the para position of Phe(4) decreased binding affinity at both delta and mu receptors in standard radioligand binding assays; the one exception was N, N-dibenzyl[Phe(p-NCS)(4)]leucine enkephalin (2) which exhibited a 2-fold increase in affinity for delta receptors (IC(50) = 34.9 nM) compared to N,N-dibenzylleucine enkephalin (IC(50) = 78.2 nM). The decreases in mu receptor affinities were greater than in delta receptor affinities so that all of the analogues tested exhibited significantly greater delta receptor selectivity than the unsubstituted parent peptides. Of the target peptides tested, only N, N-dibenzyl[Phe(p-NCS)(4)]leucine enkephalin (2) exhibited wash-resistant inhibition of radioligand binding to delta receptors. To our knowledge, 2 represents the first peptide-based affinity label to utilize an isothiocyanate group as the electrophilic affinity labeling moiety. As a result of this study, enkephalin analogue 2 emerges as a potential affinity label useful for the further study of delta opioid receptors.     

Chronic administration of morphine and naltrexone up-regulate mu-opioid binding sites labeled by [3H][D-Ala2,MePhe4,Gly-ol5]enkephalin: further evidence for two mu-binding sites

A variety of data support the hypothesis of an opiate receptor complex composed of distinct, yet interacting mu and delta binding sites (termed mu cx and delta cx to indicate binding sites 'in the complex'), in addition to independent mu and delta binding sites, termed mu ncx and delta ncx, to indicate binding sites 'not in the complex'. Ligand binding studies using membranes and slide-mounted sections of rat brain support the hypothesis that the irreversible mu-antagonist beta-funaltrexamine (FNA) selectively alkylates the opiate receptor complex, altering the binding of mu agonists to the mu cx binding site and the binding of [3H][D-Ala2,D-Leu5]enkephalin to the delta cx site. Previous studies demonstrated that the chronic administration of morphine to rats selectively 'upregulates' the opiate receptor complex. In contrast, the chronic administration of naltrexone upregulates several types of opioid receptors, including kappa, the delta ncx binding site, and multiple binding sites labeled by mu agonists. A prediction based upon these observations is that, using [3H][D-Ala2,MePhe4,Gly-ol5]enkephalin to label mu binding sites, chronic morphine should upregulate only the mu cx binding site, whereas chronic naltrexone should additionally up-regulate the mu ncx binding site. In this study we test and confirm this hypothesis, using sensitivity to FNA to define the mu cx binding site. The implications of these data for models of the opioid receptors and the mechanism(s) of tolerance and dependence are discussed.     

Cyclic enkephalin analogs containing various para‐substituted phenylalanine derivatives in place of Tyr1 are potent opioid agonists*

Abstract: The cyclic enkephalin analog H‐Tyr‐c[d ‐Cys‐Gly‐Phe(pNO₂)‐d ‐Cys]NH₂ is a highly potent opioid agonist with IC₅₀s of 35 pm and 19 pm in the guinea‐pig ileum (GPI) and mouse vas deferens (MVD) assays, respectively. The Phe¹‐analog of this peptide showed 370‐fold and 6790‐fold lower agonist potency in the GPI and MVD assays, respectively, indicating the importance of the Tyr¹ hydroxyl‐group in the interaction with μ and δ opioid receptors. In the present study, the effect of various substituents (‐NH₂, ‐NO₂, ‐CN, ‐CH₃, ‐COOH, ‐COCH₃, ‐CONH₂) introduced in the para‐position of the Phe¹‐residue of H‐Phe‐c[d ‐Cys‐Gly‐Phe(pNO₂)‐d ‐Cys]NH₂ on the in vitro opioid activity profile was examined. Most analogs showed enhanced μ and δ agonist potencies in the two bioassays, except for the Phe(pCOOH)¹‐analog, which was weakly active, probably as a consequence of the negative charge. The most potent compounds were the Phe(pCOH₃)¹‐ and the Phe(pCONH₂)¹‐analogs. The latter compound showed subnanomolar μ and δ agonist potencies and represents the most potent enkephalin analog lacking the Tyr¹ hydroxyl‐group reported to date. Taken together, these results indicate that various substituents introduced in the para‐position of Phe¹ enhance opioid activity via hydrogen bonding or hydrophobic interactions with the receptor. Comparison with existing structure‐activity relationship on phenolic hydroxyl replacements in morphinans indicates that these nonpeptide opiates and some of the cyclic enkephalin analogs described here may have different modes of binding to the receptor.     

Photoreactive enkephalin analogue: [D-Ala2, p-N3-Phe 4-Met 5] enkephalin

A photoreactive [D-Ala², p-N₃-Phe⁴-Met⁵]enkephalin was synthesized by classical solution peptide synthetic methods. The hydroxysuccinimide ester was used in all the coupling steps in the presence of a weak base, triethylamine. The deprotected enkephalin analogue was purified on high performance liquid chromatography using a Waters, C₁₈μBondapak reverse phase column and its purity was assessed by thin-layer chromatography. The composition of the analogue was determined and confirmed by elemental analysis and amino acid analysis. Its photoreactivity was demonstrated by the time dependent ultraviolet spectral changes on exposure to light. Competition receptor binding showed that [D-Ala², p-N₃-Phe⁴-Met⁵]enkephalin was 4-fold more potent than [D-Ala², Met⁵]-enkephalin in competing for binding to the enkephalin binding site. The data presented suggest that this photoreactive enkephalin analogue may be suitable for use in the in situ photoaffinity labeling of the enkephalin receptor.     

Use of hydrophilic diamines for bridging of two opioid peptide pharmacophores

The bivalent ligand approach, which assumes that two pharmacophores are connected by a spacer, was used to design receptor type-selective ligands for opioid receptors. The first two opioid peptide bivalent ligands with different spacer lengths containing different numbers of hydroxyl groups, (Tyr-d -Ala-Gly-Phe-NH-CH₂-CHOH-)₂ and (Tyr-d -Ala-Gly-Phe-NH-CH₂-CHOH-CHOH-)₂, were synthesized and their binding to mu, delta, and kappa opioid receptors was characterized. Both analogues were found to possess high opioid in vitro activities. The length of the hydrophilic spacer does not affect the affinity for delta receptors, whereas shorter spacer length increases affinity for mu and even more so for kappa receptors. Thus receptor type-selective peptides for opioid receptors can be designed using the bivalent approach.     

Binding of enkephalin/dextran conjugates to opioid receptors

[ala²]Enkephalin molecules were connected to dextran, and the affinities of the enkephalin/dextran conjugates for opioid receptors were studied. Two kinds of enkephalin derivatives, YaGFLGK-NH₂ and YaGFLGS′S′PS′S′PS′KP-OMe (S'represents a Sar residue) were prepared. They retained the high affinity of the enkephalin unit toward opioid receptors. On the other hand, receptor affinity of the enkephalin derivative dextran conjugates became lower than that of the enkephalin derivatives. Fluorescence from the Tyr residue of the conjugates in a buffer solution was less quenched by succinimide than that of the enkephalin derivatives. Therefore, in these conjugates, the binding of the enkephalin moieties to receptors should be hindered by a steric effect of the dextran matrix. However, the receptor affinity (as defined on the basis of an enkephalin unit) increased on increasing the amount of enkephalin units connected to the dextran matrix, especially in the case of the connection through a shorter spacer arm, suggesting simultaneous binding to a few receptors by the conjugate.     

Pharmacological profiles of fentanyl analogs at mu, delta and kappa opiate receptors.

Receptor binding assays using [3H]DAGO ([D-Ala2,MePhe4-Gly5-ol]enkephalin) (mu), [3H]DPDPE ([D-Pen2,D-Pen5]enkephalin) (delta) and [3H]U-69593 (kappa) were done in guinea pig whole brain membranes. Agonist activity was determined in norbinaltorphimine or beta-funaltrexamine (beta-FNA) treated guinea pig ileum (mu and kappa, respectively) and beta-FNA-treated mouse vas deferens (delta). The compounds with highest affinity were the most potent at the mu-receptor. The selectivity observed in the binding affinities was also found in in vitro activity. No correlation was found between mu-affinity and selectivity; the highest affinity analog, lofentanil, was found to be among the least selective, while another high affinity analog, R30490, was the most mu-selective. The results show that not all fentanyls are highly mu-selective, and could produce actions through delta- and kappa-opiate receptors.     

Single residue modifications of the delta opioid receptor selective peptide, [d-Pen2,d-Pen5]-enkephalin (DPDPE)

Six analogs of the highly delta opioid receptor selective, conformationally restricted, cyclic peptide [d -Pen²,d -Pen⁵]enkephalin, Tyr-d -Pen-Gly-Phe-d -PenOH (DPDPE), were synthesized and evaluated for opioid activity in rat brain receptor binding and mouse vas deferens (MVD) smooth muscle assays. All analogs were single amino acid modifications of DPDPE and employed amino acid substitutions of known effects in linear enkephalin analogs. The effect on binding affinity and MVD potency of each modification within the DPDPE structural framework was consistent with the previous reports on similarly substituted linear analogs. Conformational features of four of the modified DPDPE analogs were examined by ¹H NMR spectroscopy and compared with DPDPE. From these studies it was concluded that the observed pharmacological differences with DPDPE displayed by diallyltyrosine¹-DPDPE ([DAT¹]DPDPE) and phenylglycine⁴-DPDPE ([Pgl⁴]DPDPE) are due to structural and/or conformational differences localized near the substituted amino acid. The observed enhanced μ receptor binding affinity of the carboxamide terminal DPDPE-NH₂ appears to be founded solely upon electronic differences, the NMR data suggesting indistinguishable conformations. The observation that the α-aminoisobutyric acid substituted analog [Aib³]DPDPE displays similar in vitro opioid behavior as DPDPE while apparently assuming a significantly different solution conformation suggests that further detailed conformational analysis of this analog will aid the elucidation of the key structural and conformational features required for action at the δ opioid receptor.     

Synthesis of a potent enkephalin analog,Tyr-D-Thr-Gly-Phe-Δ3Pro-NH2, and some of its biological activities

The enkephalin analog, H-Tyr-D-Thr-Gly-Phe-Δ³Pro-NH₂ x HCl (VI)([D-Thr², Δ³Pro⁵]-enkephalinamide), has been synthesized by conventional methods in solution and purified to homogeneity by reversed phase HPLC. The analog is a potent analgesic agent. For evaluation of some of its biological activity a related compound [D-Thr², Thz⁵]-enkephalinamide (XI) was also synthesized in solution. Anti-diarrhea activity was evaluated in mice by the intravenous route for anti-DL-5-hydroxytryptophan (5-HTP) induced diarrhea activity. Analgesic activity was assayed by the method of Nilsen in mice using the intravenous route, and by a modified tail flick test in rats and the acetic acid writhing test in mice following subcutaneous administration. Within the constraints of the assays the two analogs are approximately equipotent. Both are less active than [D-Ala², MePhe⁴, Met(0)ol]-enkephalinol (XII). Earlier receptor binding studies of compound XI indicated enhanced affinity for the μ receptor and little for the δ receptor. By comparison this may also be the case for compound VI.     

Synthesis and biological activity of linear and cyclic enkephalins modified at the Gly3-Phe4amide bond

As part of our continuing effort to define structure-activity relationships for enkephalin and design enzymatically resistant analogs, we report the synthesis and biological activities of linear and cyclic enkephalin analogs modified at the Gly³-Phe⁴amide bond. The partial retro-inverso enkephalin analog Tyr-d -Ala-gGly-(R,S)-mPhe-Leu-NH₂ and its cyclic counterpart, Tyr-cyclo[d -A₂bu-gGly-(R,S)-mPhe-Leu-], were synthesized as diastereomeric mixtures using solution methodology. The racemic benzylmalonate allowed the linear analog to be synthesized by fragment coupling at the reversed bond. Cyclization of the second analog was carried out at high concentration, eliminating formation of polymer by the use of an insoluble base. All gem-diaminoalkyl residues were prepared by conversion of peptidyl amides with benzene iodonium bis(trifluoroacetate). Diastereomers of both compounds were separable by reverse phase HPLC but those of the linear compound racemized rapidly under conditions of testing and were therefore tested together. All analogs tested had activities ranging from 6 to 14% of the activity of Leu enkephalin, indicating that the Gly³-Phe⁴amide bond is important, though not crucial, for receptor binding.     

Dehydro-enkephalins

The Gly³ residue in Gly²- and D-Ala²-enkephalins has been replaced by ΔAla³ and Ser³ in order to examine the effect on binding to the Δ and μ opiate receptors. [D-Ala², ΔAla³, Leu⁵]-enkephalin maintains most of its receptor binding affinities for both sites. It is suggested that the proper conjunctions of positions 2 and 3 of the enkephalin sequence are important to receptor preference and that position 3 may have a very specific interaction with the Δ receptor. The in vivo analgesic and CNS activities of the peptides are also discussed.     

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.     

Site-directed alkylation of multiple opioid receptors. I. Binding selectivity

We report a method for measuring and expressing the binding selectivity of ligands for mu, delta, and kappa opioid binding sites. We used radioligands that are partially selective for these sites in combination with membrane preparations enriched in each site. Enrichment was obtained by treatment of membranes with the alkylating agent beta-chlornaltrexamine in the presence of appropriate protecting ligands, sufentanil for mu sites, [D-Ala2, D-Leu5] enkephalin for delta sites, and dynorphin A for kappa sites. After enrichment for mu receptors, [3H] dihydromorphine bound to a single type of site as judged by the slope of competition binding curves. After enrichment for delta or kappa receptors, binding sites for [3H] [D-Ala2, D-Leu5]enkephalin and [3H]ethylketocyclazocine, respectively, were still not homogeneous. There were residual mu sites in delta-enriched membranes but we found no evidence for residual mu or delta sites in kappa-enriched membranes. We used this method to identify ligands that are highly selective for each of the three types of sites: Tyr-D-Ala-Gly-(Me)Phe-Gly-ol, sufentanil, and morphiceptin for mu sites; (D- Pen2 , D- Pen5 ]enkephalin and [D- Pen2 ,L- Pen5 ]enkephalin for delta sites; and tifluadom and U50 ,488 for kappa sites.     

Probing opioid receptor–ligand interactions by employment of indolizidin‐9‐one amino acid as a constrained Gly2‐Gly3 surrogate in a leucine‐enkephalin mimic

Abstract: The relationship between the conformation and biological activity of Leu‐enkephalin was studied using (2S,6R,8S)‐9‐oxo‐8‐N‐(Boc)amino‐1‐azabicyclo[4.3.0]nonane‐2‐carboxylic acid [(2S,6R,8S)‐ 1 , I⁹AA] as a constrained Gly²‐Gly³ dipeptide surrogate. [I⁹AA]^2,3‐Leu‐enkephalin 12 was assembled using solid‐phase peptide synthesis on Merrifield resin with TBTU as the coupling reagent. The in vitro assays indicated that [I⁹AA]^2,3‐Leu‐enkephalin 12 exhibited affinities for the µ‐ and δ‐opioid receptors that were three orders of magnitude lower than that of Leu‐enkephalin, as well as partial agonist character for both receptors. In in vivo assays for spinal analgesia, the indolizidinone analog 12 showed significantly enhanced duration of action, indicating an increased metabolic stability. Conformational analysis was performed using NMR and CD spectroscopy. The amide temperature coefficients and ³J_NH‐CαH coupling constants for 12 could not support a hydrogen‐bonded β‐turn structure; however, its CD spectrum indicated a turn conformation. Incorporation of indolizidinone amino acid 1 into Leu‐enkephalin thus provided additional support for the importance of a turn conformation for the biological activity of the native peptide.     

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.     

Synthesis,receptor binding activity and fluorescence property of fluorescent enkephalin analogs containing L-1-pyrenylalanine

The novel fluorescent amino acid, l -1-pyrenylalanine (l -Pya), was prepared by the asymmetric hydrogenation of cyclic dehydrodipeptide. Fluorescent enkephalins containing one or two Pya residues at position 1, 4 or 5 of [d -Ala², Leu⁵]enkephalin were synthesized by the solution method. Mono-Pya-enkephalins showed strong fluorescence intensities and potent binding affinities with specificity and selectivity for opiate receptors. However, di-Pya-enkephalins showed markedly decreased receptor binding affinities. These results indicate that the incorporation of two Pya residues into enkephalin makes the peptide unable to interact with the opiate receptors, although introduction of one Pya residue is effective to elicit a specific receptor interaction. Di-Pya-enkephalins showed intramolecular excimer spectra, indicating that the peptides are able to take possible folded conformations.     

Selectivity of ligand binding to opioid receptors in brain membranes from the rat, monkey and guinea pig

Conditions for the equilibrium binding to opioid receptor of [3H]sufentanil (mu selective), [3H][D-Pen2,D-Pen5]enkephalin (delta selective), and [3H]U69,593 (kappa selective) were established in membranes from rat brain cerebrum, monkey cortex, or guinea pig cerebellum. The selectivity index of various opioid alkaloids and peptides in binding to the mu, delta, or kappa opioid receptors was expressed as the ratio of their EC50 values in displacing two selective radiolabeled ligands: [3H]sufentanil/[3H](D-Pen2,D-Pen5)enkephalin (selectivity: mu/delta), [3H]sufentanil/[3H]U69,593 (selectivity: mu/kappa), or [3H][D-Pen2,D-Pen5]enkephalin/[3H]U69,593 (selectivity: delta/kappa). High resolution in binding selectivity was observed: in rat brain the mu/delta selectivity for Tyr-D-Ala-Gly-(Me)Phe-Gly-ol and sufentanil were 0.02 and 0.03, whereas for [D-Pen2,D-Pen5]enkephalin and ICI 174,864 they were 1,200 and 998. Compared to mu opiates, the specific binding of delta and kappa agonists was less sensitive to sodium. The results describe a routinely applicable methodological approach for the assessment of selective ligand binding to the mu, delta and kappa opioid receptors in rodent and monkey brain membranes.