K. Medzihradszky

Adrenal cortex - a newly recognized peripheral site of action of enkephalins.

Summary Two naturally occuring enkephalins, Leu- and Met-enkephalin, were shown to inhibit adrenal corticosteroid biosynthesis. In isolated rat adrenal cell system corticosterone, desoxycorticosterone and aldosterone, and in isolated bovine adrenal cells cortisol, corticosterone and aldosterone production were markedly depressed in a dose-dependent fashion, both under basal conditions and following stimulation with ACTH 1–24 . The inhibitory action of enkephalins on corticosteroid synthesis could be augmented by increasing the Ca 2+ -concentration in the cell-containing medium. The demonstration that opioid peptides interfere with corticosteroidogenesis directly at the adrenal level points to the existence of a peripheral neuroendocrine relationship.

Purification of a kappa-opioid receptor subtype from frog brain

A kappa-opioid receptor subtype was purified from a digitonin solubilized preparation of frog brain membranes using affinity chromatography. The affinity resin was prepared by coupling D-Ala2-Leu5-enkephalin to Sepharose-6B matrix. After elution of the receptor by 50 mumol naloxone, the kappa-subtype was separated from the mu- and delta-subtypes by gel permeation chromatography on Sepharose-6B. The purified receptor binds 3,900 pmol [3H]-ethylketocyclazocine per mg protein (a 4,300-fold purification over the membrane-bound receptor) with a KD of 8.3 nM. The purified receptor protein exhibits high affinity for kappa-selective ligands. The purified fraction shows two bands (Mr 65,000 and 58,000) in sodium dodecyl sulfate gel electrophoresis.

Tyr-D-Ala-Gly-(Me)Phe-chloromethyl ketone: A mu specific affinity label for the opioid receptor

An alkylating tetrapeptide enkephalin derivative, Tyr-D-Ala-Gly-(Me)Phe-chloromethyl ketone (DAMK) was synthesized, and its binding characteristics on rat brain membranes were evaluated. In competition experiments, the product shows high affinity for the mu opioid binding site of the rat brain membranes, whereas its binding to the delta and kappa subtypes is weak. Micromolar concentrations of this ligand produce a dose-dependent, apparently irreversible inhibition of /3H/-naloxone binding, with apparent IC50 value of 1-5 uM. Neither reversibly binding opioids nor tosyl-amino acid chloromethyl ketones show these effects. Saturation binding analysis with /3H/-naloxone of membranes preincubated with Tyr-D-Ala-Gly-(Me)Phe-CH2Cl reveal a selective and irreversible inhibition of the high affinity /3H/-naloxone binding site. Irreversible blockade of mu-selective /3H/-ligand binding by Tyr-D-Ala-Gly-(Me)Phe-CH2Cl is much more effective than that of the binding of /3H/-enkephalin or /3H/-ethylketocyclazocine. The mu-selective binding properties of this new irreversible enkephalin analogue suggest that it could serve as an affinity label for the mu opioid receptor subtype.

Binding characteristics and analgesic activity of D-Ala2-Leu5-enkephalin chloromethyl ketone

The chloromethyl ketone derivative of D-Ala2-Leu5-enkephalin (DALECK) was synthesized and its potency was tested in competing for 3H-naloxone binding sites and inducing analgesia. It was established that the compound is a potent affinity reagent at alkaline pH, blocking selectively and irreversibly the high-affinity (KD less than 1 nM) binding site. Intracisternally given DALECK showed a long-lasting, dose-dependent antinociceptive effect in the rat tail-withdrawal test. This could be completely antagonized by naloxone administration showing the reversible nature of DALECK in this in vivo assay. It is suggested that DALECK binds reversibly to the morphine receptor which mediates analgesia but irreversibly to the enkephalin receptor, the function of which remains to be elucidated.

Covalent labeling of opioid receptors with 3HDAla2Leu5-enkephalin chloromethyl ketone II. Binding characteristics in frog brain membranes

3H-D-Ala2-Leu5-enkephalin chloromethyl ketone (3H-DALECK) was used to label opioid receptors of frog brain membranes. We have previously shown (15) that 70% of the opioid receptors are of kappa type in this preparation. The binding of 3H-DALECK was of high affinity, half maximal binding being achieved by 0.9 nM of the radioligand. The number of sites labeled was calculated to be 108 fmol/mg protein. Opioid ligands, incubated with the membranes prior to the label, inhibited 3H-DALECK binding with the following rank order:etorphine greater than EKC greater than DAGO greater than DALECK greater than DADLE. Dissociation experiments showed that 70% of the binding is irreversible. Fluorography performed after SDS-PAGE revealed specific covalent labeling of protein subunits of 90, 58 and 20 kD molecular weights. Results will be compared to those obtained in rat brain (13). Our two studies demonstrate that 3H-DALECK is a useful probe for investigation the subunit structure of opioid receptors.

Characterization of rat brain opioid receptors by [Tyr-3,5-3H]1, d-Ala2, Leu5-enkephalin binding

Abstract[Tyr-3,5-3H]1,d-Ala2, Leu5-enkephalin ([3H]DALA) was used for labeling the opioid receptors of rat brain plasma membranes. The labeled ligand was prepared from [Tyr-3,5-diiodo]1,d-Ala2, Leu5-enkephalin by catalytic reductive dehalogenation in the presence of Pd catalyst. The resulting [Tyr-3,5-3H]1,d-Ala2, Leu5-enkephalin had a specific activity of 37.3 Ci/mmol. In the binding experiments steady-state level was reached at 24°C within 45 min. The pseudo first order association rate constant was 0.1 min−1. The dissociation of the receptor-ligand complex was biphasic with k−1-s of 0.009 and 0.025 min−1. The existence of two binding sites was proved by equilibrium studies. The high affinity site showed aKD=0.7 nM andBmax=60 fmol/mg protein; the low affinity site had aKD=5 nM andBmax=160 fmol/mg protein. A series of opioid peptides inhibited [3H]DALA binding more efficiently than morphine-like drugs suggesting that labeled ligand binds preferentially to the δ subtype of opioid receptors. Modification of the original peptides either at the C or N terminal ends of the molecules resulted in a decrease in their affinity.

Irreversible labelling of rat brain opioid receptors by enkephalin chloromethyl ketones.

Chloromethyl ketone derivatives of leucine enkephalin (LE), D-Ala2-Leu5-enkephalin (DALE) and D-Ala2-D-Leu5-enkephalin (DADLE) were synthesized. They all show high affinity for rat brain opioid binding sites. Preincubation of the membrane fraction with enkephalin chloromethyl ketones causes a significant inhibition of /3H/-naloxone binding which cannot be reversed by extensive washing. It was found that the irreversible inhibition is selective for the high affinity (KD less than 1 nM) /3H/-naloxone binding site (putative mu-1 site). The irreversible blockade of opioid binding was partially protected by opiate alkaloids and opioid peptides, suggesting that non-specific labelling also occurs. Affinity of enkephalin chloromethyl ketones toward the mu sites is greater than that of the parent compounds. It was also found that the covalent inhibition of mu sites (/3H/-dihydromorphine and /3H/-DAGO binding) is more effective than that of delta sites (/3H/-DALE binding). We conclude that these chloromethyl ketone derivatives can be used as affinity labels for the opioid receptors, allowing us to study the structure of the mu receptor subtype.

Design of Opioid Peptides for a Potential Delta-Receptor Affinity Label Function: Comparison with the Mu-Specific Tyr-D-Ala-Gly-(Me)Phe- Chloromethyl Ketone

To find a delta-opioid receptor preferring peptide structure containing an Asp residue in a potentially interacting position, Tyr-Pro-Phe-Asp, Tyr-D-Ala-Phe-Asp, Tyr-D-Ala-Gly-Phe-Asp, Tyr-D-Ala-Gly-Phe-Asp alpha- and beta-methyl ester and Tyr-Gly-Gly-Phe-Asp peptides were synthesized and their biological activities were analyzed in vitro in mouse vas deferens and longitudinal muscle strip of guinea pig ileum. Changing the beta-methyl ester for an alkylating chloromethyl ketone moiety in the delta-receptor-selective agonist Tyr-D-Ala-Gly-Phe-Asp-beta-methyl ester enhanced further the delta-receptor preference. The delta-receptor selective chloromethyl ketone but not the beta-methyl ester gave a very slow washout after prolonged incubation in the mouse vas deferens bioassay; however, it was still readily displaceable by naloxone. The washout pattern of mu-specific Tyr-D-Ala-Gly-(Me)Phe chloromethyl ketone did not differ in the bioassays from that of the corresponding Gly5-ol derivative. Both chloromethyl ketones gave irreversible characteristics in the receptor binding assay.

Melphalan potently substitutes the N-terminal Tyr of D-Ala2-Leu5-enkephalin methyl ester

In search of an affinity label of the opioid receptor, the nitrogen mustard melphalan, Mel, was built into the peptide chain of D‐Ala2‐Leu5‐enkephalin (DALE) methyl ester in different positions. We report now that in contrast to the previous observations that an intact Tyr in position 1 is essential for opioid activity [(1980) Annu. Rev. Pharmacol. Toxicol. 20, 81‐110], substitution of Tyr by Mel did not result in a loss of the binding affinity. Mel1, Leu5‐enkephalin‐OMe competed for the binding sites of [3H]naloxone as potently as DALE did; IC50 values for both compounds were 50 nM. Mel substitution has led to one order potency decrease in binding to the δ‐sites. 0.5–1 μM of the compound irreversibly inactivates 50% of the binding sites of [3H]naloxone, and 5–10 μM of that of [3H]DALE. These results shed new light on the structural requirements established for opioid peptides. In addition, the new derivative can be used as an affinity label of the opioid receptor.

Synthesis of 3H-Tyr-D-Ala-Gly-N(Me)Phe chloromethyl ketone-an opioid affinity label

A radioactive enkephalin affinity reagent, selective for the mu opioid receptor subtype, was synthesized by a fragment condensation method. 3H-BOC-Tyr-D-Ala-Gly-OH was prepared by catalytic tritiation of the protected iodinated tripeptide. The protected tritiated tripeptide and N(Me)Phe-CH2Cl were condensed by the mixed anhydride method. The protecting group was removed by HCl/acetic acid. The tritiated tetrapeptide has a specific radioactivity of 56.8 Ci/mmole (2.1 TBq/mmole).