Alcohol interactions with brain opiate receptors

Ethanol, added $\text{in vitro}$ to mouse caudate membranes, inhibited high-affinity binding of 0.2 nM ³H-dihydromorphine (³H-DHM) over an ethanol concentration range of 250–1,000 mM. At lower, physiologically-attainable ethanol concentrations (e.g.: 50 mM), ³H-DHM binding was significantly increased. Over the concentration range of 50–1,000 mM, ethanol inhibited 0.5 nM ³H-[D-Ala², D-Leu⁵] enkepha l in (³H-ENK) binding to mouse caudate tissue, and no stimulation of Ethanol inhibits opiate binding in a pseudo-competitive manner and, therefore, the concentration of ligand used to assess the effects of ethanol is of major importance. Results obtained with other alcohols which differ in their membrane: water partition coefficients suggest that alcohol effects on opiate binding are not solely dependent on the membrane-disordering properties of the alcohols.     

Effect of apomorphine on rat brain opiate receptors

Stereospecific binding of apomorphine to rat brain opiate receptors was shown by assaying the competition of 7,8(n)--3H--naloxone and D-ala2-tyrosyl-3,5-3H--enkephalin (5-D-leucine) for opiate receptor binding. EC-NaCl50, the concentration of apomorphine which inhibited 50% binding of the radioactive naloxone and D-ala2, D-leu5-enkephalin in the absence of NaCl were 20 and 42 microM, respectively. EC+NaCl 50, the concentration of apomorphine which inhibited 50% binding of the radioactive naloxone in the presence of 100 mM NaCl was 17 microM. From the ratio of EC+NaCl 50 to EC-NaCl the value of "sodium shift" of effective concentration can be calculated as 0.85. From the data obtained it is concluded that apomorphine, like naloxone, is a "pure" antagonist but it has much less affinity for enkephalin and opiate binding sites. The probable mechanisms of the pharmacological action of apomorphine are discussed.     

Effect ot thyroliberin on rat brain opiate receptors

The ability of thyroliberin to interact with opiate receptors of the rat midbrain and hypothalamus has been studied. It was shown by competitive displacement analysis that thyroliberin did not replace labeled opioid peptides in opiate receptor binding sites when added in vitro at concentrations of up to 10(-5) M. The specific binding of opioid peptides was increased by 10-20% in the presence of 10(-7)-10(-6) M thyroliberin. This effect was, probably, due to the rise in the affinity of high-affinity opiate receptors. At the same time the affinity of low-affinity binding sites was decreased. It is suggested that the antagonistic properties of thyroliberin are mediated by the modulation of the binding characteristics of enkephalin-low-affinity opiate receptors.     

Alpha interferon interaction with opiate receptors in the rat brain

The preferential interactions of alpha-interferon (alpha-IFN) with delta and mu opiate receptors were studied. alpha-IFN (specific antiviral activity 2 X 10(3) U/mg protein) was shown to inhibit in the competitive manner 3H-naloxone and 3H-D-ala2, D-leu5-enkephalin (3H-DADL) specific binding to opiate receptor subpopulations. alpha-IFN was much more effective in decreasing 3H-DADL than 3H-naloxone binding in opiate receptors: K1 values averaged 160 +/- 30 and 1150 +/- 80 U/ml, respectively. IFN effective concentrations inhibiting 50% of 3H-naloxone opiate receptor binding in the absence or presence of 100 mmol/l NaCl were similar, and the "sodium shift" value was equal to 1. The independence of alpha-IFN activity of the presence of NA+ cations suggests the antagonist character of alpha-IFN interaction with opiate receptors. Thus, alpha-IFN employed appears to be an alpha-selective ligand displaying the in vitro properties of "pure" morphine antagonists.     

Visualization of opiate receptors and opioid peptides in sequential brain sections

Autoradiographic and immunocytochemical studies were carried out on adjacent sections from formaldehyde-perfused rat brains in order to directly correlate the distribution of opiate receptors and opioid peptides. Perfusion fixation of the brains resulted in a partial loss of specific [3H]naloxone binding with essentially no change in the pharmacological properties of the remaining sites. When the distribution of sites was compared to that of enkephalin immunoreactivity in adjacent sections, striking correlations were observed in a number of areas throughout the neuraxis. Adjacent section autoradiography-immunocytochemistry should provide a useful tool for relating the anatomical distribution of opiate receptor subtypes to different opioid peptide neuronal systems.     

Lectin binding of solubilized opiate receptors: evidence for their glycoprotein nature

Lectin affinity chromatography was used to demonstrate that digitonin-solubilized opiate receptors contain a carbohydrate moiety. Receptors solubilized from toad, rat, chicken, bovine and human brains were retained on columns of wheat germ agglutinin (WGA)-agarose and eluted specifically with N-acetylglucosamine. The fraction retained and subsequently eluted ranged from 40–60% of the applied receptors. The eluted receptor was enriched approx. 30-fold. Evidence is presented which shows that the site of lectin interaction is functionally independent of the opiate binding site.     

Selective proliferation of brain kappa opiate receptors in spontaneously hypertensive rats

The binding of tritiated ligands for various opiate receptor subtypes to brain membranes prepared from spontaneously hypertensive rats and normotensive Wistar-Kyoto rats was determined. The density (Bmax) or the apparent dissociation constant (Kd) for the binding of the mu-ligand (naltrexone) and delta-ligand (Tyr-D-Ser-Gly-Phe-Leu-Thr) to brain membranes of hypertensive and normotensive rats did not differ. However, the Bmax for the binding of kappa-ligand (ethylketocyclazocine, EKC) to brain membranes after the suppression of mu and delta-sites by 100 nM each of unlabeled D-Ala2-MePhe4-Gly-ol5-enkephalin and D-Ala2-D-Leu5-enkephalin, respectively, was significantly greater in hypertensive rats compared to normotensive rats. The Kd values for the binding of 3H-EKC in the two groups did not differ. The binding of 3H-EKC in brain regions was in the order: hypothalamus greater than midbrain greater than striatum greater than cortex greater than pons + medulla. The increase in the binding of 3H-EKC in the brain of hypertensive rats compared to normotensive rats was due to increased binding in the hypothalamus and cortex. These results provide for the first time evidence of selective proliferation of kappa-opiate receptors in the brain of hypertensive rats, and suggest that brain kappa-opiate receptors may play an important role in the pathophysiology of hypertension.     

The molecular structure of opiate receptors

Examples are given which demonstrate that the opiate receptor can be separted from and subtypes by their physical parameters. When the subunit composition of the subtypes are compared, no definite differences are encountered. The data from the literature are also contradictory. This may in part be explained by the fact that the different receptors appear to contain a structurally common high affinity binding site. A possible hypothesis would be that the subtypes differ from each other by the number of subunits.Abbreviations CHAPS 3/cholamidopropyl-dimethylammonio 1-propansulfonate - DAGO D-Ala ²-Me-Phe⁴-Gly-ol⁵-enkephalin - DALA d-Ala²-Leu⁵-enkephalin - DALECK d-Ala²-Leu⁵-enkaphalin chloromethyl ketone - EGF Epidermal growth factor - EKC ethylketocyclazocine - SDS-PAGE Sodiumdodecylsulfate polyacrylamide gel elecctrophoresis Special Issue Dedicated to Dr. Abel Lajtha.     

Development of opiate receptors and GTP-binding regulatory proteins in neonatal rat brain

The mu and delta opiate receptors present in rat brain were measured independently during postnatal development. The numbers of delta receptors were almost undetectable at birth and increased substantially during the first few weeks, whereas the numbers of mu receptors remained relatively constant. Activation of either of these receptors caused inhibition of adenylate cyclase, but inhibition coupled to mu receptors was much smaller than that associated with delta receptors at all ages. Attempts to use pertussis toxin-catalyzed ADP-ribosylation as an assay for the GTP-binding proteins Ni and No were hampered by the development of an NADase with age. However, specific antibodies directed against the alpha subunits of Ni or No allowed separate quantitation of these transducer proteins. Both increased with age. No is present at levels at least 5-fold higher than Ni in the adult rat brain. The N proteins are in vast excess over receptors and as such are unlikely to be limiting factors in receptor function. The data further suggest that the number of opiate receptors present throughout neonatal development is in excess over that required for optimal function.     

Cholecystokinin-8 suppressed 3H-etorphine binding to rat brain opiate receptors

Radio receptor assay (RRA) was adopted to analyse the influence of CCK-8 on 3H-etorphine binding to opiate receptors in rat brain synaptosomal membranes (P2). In the competition experiment CCK-8 (1pM to 1 microM) suppressed the binding of 3H-etorphine. This effect was completely reversed by proglumide at 1 microM. Rosenthal analysis for saturation revealed two populations of 3H-etorphine binding sites. CCK-8 (1pM to 1 microM) inhibited 3H-etorphine binding to the high affinity sites by an increase in Kd (up to +235%) and decrease in Bmax (up to -80%) without significant changes in the Kd and Bmax of the low affinity sites. This effect of CCK-8 (10nM) was also completely reversed by proglumide at 1 microM. Unsulfated CCK-8 (100pM to 1 microM) produced only a slight increase in Kd of the high affinity sites (+64%) without affecting Bmax. The results suggest that CCK-8 might be capable of suppressing the high affinity opioid binding sites via the activation of CCK receptor.     

Evidence contradicting the notion that gonadal hormones regulate brain opiate receptors

Castration of male rats has been reported to increase brain opiate receptors by nearly 100%. We assayed brain opiate receptors with both naloxone and met-enkephalin, but found no effect of gonadectomy on the Kd or Bmax for either ligand in male or female mice or in male rats. Experiments were performed with 2 strains of mice and 3 strains of rats; mice were gonadectomized 1–7 weeks and rats were castrated 3 weeks before assay. Both washed and unwashed brain membrane preparations were used. Administration of testosterone or estrogen to intact male or female mice did not alter opiate receptors. Castration did not affect the strain or age and brain-region differences found for naloxone binding in male rats.     

The nature of receptors regulating the formation of cyclic AMP in brain tissue.

Extensive studies of the past seven years have provided fundamental information on the pharmacological properties of receptors controlling formation of cyclic AMP in brain slices and homogenates. Receptors for adenosine, α- and β-adrenergic agonists, dopamine, serotonin, H₁- and H₂-histaminergic agonists, and prostaglandins of the E series have been defined and evidence for a glutamate receptor has been presented. Extrapolation of such pharmacological data to studies with whole animals should provide important information as to the physiological significance of specific cyclic AMP-generating systems to the function of the intact brain.     

Characteristics of opiate receptors in the brain and spinal cord of morphine tolerant mice

The in vitro studies of 3H-morphine binding to synaptosomal brain and spinal cord membranes and the in vivo detection of pA2 values were carried out in mice. Both morphine-tolerant and intact animals were used. Morphine-tolerant mice showed no changes in specific binding and naloxone pA2 values. Desensitization of neural tissue is most likely to result from variation in translation from opiate receptors to subreceptor effector systems.     

Stability of opiate receptors of wet and lyophilized preparations of rat brain membranes

The effects of incubation of rat brain membranes at 0 degrees C on the specific binding of mu-ligands (naloxone, morphine) and the delta-ligand (D-Ala2, D-Leu5-enkephalin) to opiate receptors were studied. The effects of lyophilization of rat brain membranes on the properties of the opiate receptors were determined. The lyophilized brain membrane preparations revealed an extraordinarily high stability as compared to "wet" membranes. The experimental results suggest that morphine and D-Ala2, D-Leu5-enkephalin binding both to the high affinity and low affinity sites has different nature and point to the utility of stable and standard preparations of lyophilized membranes for the use in the receptor analysis of opiate and opioid peptides.     

Regional analysis of brain opiate receptors in rats with hereditary hypothalamic diabetes insipidus.

The regional distribution of stereospecific ³H-dihydromorphine binding sites in Brattleboro rats with hereditary hypothalamic diabetes insipidus was studied. Control animals were homozygous normal Brattleboro rats and rats heterozygous for the vasopressin deficiency. Scatchard plots of ³H-dihydromorphine binding in a washed membrane preparation showed that rats with diabetes insipidus exhibited higher receptor concentrations in all assayed areas of the cerebral hemispheres. In the diencephalon, receptor concentrations were lower in diabetes insipidus rats. The results point to the existence of interactions between brain opioid systems and neurohypophyseal peptides.     

Multiple opiate receptors in guinea-pig ileum

Actions of the prototypic μ-, κ-, and σ-opiate receptor agonists, morphine (M) ketocyclazocine (K) and SKF-10,047. (S), respectively, were examined and differentiated using the guinea-pig ileum preparation. S, like M and K, depressed the electrically stimulated ileum. Naloxone antagonized the depressant actions of the prototypic drugs with different potencies. PA₂ values of naloxone for M, K, and S, respectively, were 8.81, 7.58 and 7.74. Relative cross tolerance of each prototypic drug to normorphine, a comparison standard, was also examined in morphine-pretreated ilea and quantitatively estimated as follows: (1) the median effective dose of each drug and of the standard drug normorphine were determined in the nontolerant ileum (IC50_NT) and in ilea with varying degrees of tolerance IC50_T); (2) cross-tolerance ratios (IC50_T/IC50_NT) of each drug and of normorphine were calculated for the varying degrees of tolerance; (3) cross-tolerance ratios of each drug were plotted against those of normorphine, the data were fit by a least squares straight line, and the slope of the line determined as the Relative Cross Tolerance Index (RCTI). RCTI for M was 2.21. K and S, however, had lower RCTI's of 0.44 and 0.64 respectively. In the morphine-pretreated tolerant ilea, slopes of the dose response curves of the prototypic drugs were found to differ: while M and K possessed steep and constant slopes for ilea with different degrees of tolerance, the slopes for S became shallower as ilea became more tolerant to morphine. A maximum ceiling effect of less than 50% depression was obtained for S in the most highly tolerant ilea. The above observations are consistent with possible existence of the three types of hypothesized opiate receptors in the guinea-pig ileum.