Sodium regulation of agonist binding at opioid receptors. I. Effects of sodium replacement on binding at mu- and delta-type receptors in 7315c and NG108-15 cells and cell membranes

The effects of varying the sodium concentration (at constant ionic strength) on opioid binding at mu- and delta-opioid receptors in 7315c and NG108-15 cells has been examined. The binding of [3H]etorphine to mu-receptors on 7315c cells was increased by replacing the sodium in the incubation medium with potassium or N-methyl-D-glucamine. This effect was shown to be attributable to an increase in affinity, with no change in the maximum number of binding sites, both in cell membrane suspensions and in intact 7315c cells. Replacement of sodium with potassium or N-methyl-D-glucamine in NG108-15 membrane or intact cell suspensions also resulted in an increase in [3H]etorphine binding, but in these cells the effect was associated with an increase in the number of binding sites measurable under these experimental conditions. The effects of sodium on opioid inhibition of adenylate cyclase in membrane preparations from 7315c and NG108-15 cells also differed. Sodium reduced apparent agonist affinity in 7315c membranes. In NG108-15 cell membranes, sodium was essential for the demonstration of opioid inhibition of cyclase activity. Increasing the sodium concentration above 0.5 mM resulted in an increase in the fraction of total enzyme activity inhibited by opioid, but the opioid IC50 did not change. In the companion paper, it is shown that the effects of sodium removal on mu- and delta-receptor binding in guinea pig brain neural membranes were similar to those observed in the cell preparations. An increase in intracellular sodium concentration without change in extracellular concentration was effected by incubation of 7315c and NG108-15 cells with the sodium-selective ionophore, monensin. When sodium was present in the extracellular medium, monensin reduced [3H]etorphine binding by 50% or more, both at mu-receptors in 7315c cells and at delta-receptors in NG108-15 cells. In the absence of sodium, however, monensin treatment produced only a small inhibition of binding. These results suggest that sodium acts at an intracellular site to regulate opioid agonist binding at both mu- and delta-receptors, but that the mode of regulation is not identical at each site. Since a reduction in intracellular sodium concentration by removal of extracellular sodium increases agonist binding, and an increase in intracellular sodium following monensin treatment reduces agonist binding, it is probable that the intracellular sodium concentration is a critical regulator of opioid agonist binding in intact cells.

Opioid ligand binding sites in the spinal cord of the guinea-pig

The properties of opioid binding sites in membranes from the spinal cord of the guinea-pig were analyzed in experiments employing radiolabeled opioid ligands, selective or partially selective for mu, delta and kappa-type binding sites. Incubation was conducted at 37 degrees C in a quasi-physiological modified Krebs medium, containing sodium and magnesium. The types of binding sites were discriminated on the basis of their affinities for [3H-D-Ala2-MePhe4-Gly5-ol]enkephalin ([3H]DAGO), [3H-D-Ala2-D-Leu5]enkephalin, and [3H]ethylketocyclazocine and the relative potencies of the displacing ligands, DAGO, [D-Ser2-Leu5]enkephalyl-Thr and trans-3,4-dichloro-N-methyl-N-[2-(1-pyrrolidinyl)- cyclohexyl]benzeneacetamide methanesulfonate hydrate (U50488H), which are selective for mu, delta and kappa type binding sites respectively. In membranes from whole spinal cord, kappa type sites comprised about 60%, mu about 30% and delta about 10% of the total of mu, delta and kappa binding sites. Binding sites of the mu type were also found in the lumbo-sacral region of guinea-pig spinal cord, in contrast to earlier reports of their absence from this tissue. Morphine showed a better than 500-fold selectivity for mu over kappa sites in spinal cord, while nalbuphine and (-)1-cyclopentyl-5-(1,2,3,4,5,6-hexahydro-8-hydroxy-3,6,11- trimethyl-2,6-methano-3-benzazocin-11-yl)3-pentanone methanesulfonate (WIN 44441-3) showed about a 10-fold selectivity for mu sites. The drug U50488H had about a 150-fold greater affinity for kappa than mu-type binding sites.

Opioid binding to rat and guinea-pig neural membranes in the presence of physiological cations at 37 degrees C

We have identified mu, delta and kappa opioid binding sites in four types of neural membranes under conditions which include physiological concentrations of ions and an incubation temperature of 37 degrees C. We hypothesize that binding parameters determined under these conditions should be more directly comparable with physiological experiments than parameters obtained under conditions of low ionic concentration and at low temperature. By using either a radioligand which is selective for a single type of opioid binding site or a relatively nonselective radioligand in the presence of an unlabeled selective ligand, we have isolated binding to single populations of sites. Saturation and displacement data were analyzed with the aid of a computerized nonlinear curve fitting program. [3H]Tyr-D-Ala-Gly-(Me)Phe-Gly-ol bound to a single population of sites with the characteristics of mu receptors, as determined by saturation and displacement analysis. Binding to the mu site represented 70% of the total specific opioid binding in rat brain, but only 20 to 30% in guinea-pig tissues. [3H][D-Ala2-D-Leu5]enkephalin bound almost equally well to mu and delta sites, but the delta site could be examined by the inclusion of unlabeled Tyr-D-Ala-Gly-(Me)Phe-Gly-ol in the incubations. [3H]Ethylketocyclazocine bound mu and kappa sites, and Tyr-D-Ala-Gly-(Me)Phe-Gly-ol was also used to block the mu component in experiments in which we studied kappa binding. Binding to kappa sites represented 50 to 60% of the total in guinea-pig tissues, but less than 20% in rat brain.

Binding sites for L-[3H]glutamate on hippocampal synaptic membranes: three populations differentially affected by chloride and calcium ions

The effects of Cl- and Ca2+ were studied on the specific binding of L-[3H]glutamate to multiple sites on rat hippocampal synaptic membranes. Quisqualate (5 microM) or DL-2-amino-4-phosphonobutyrate (2-APB) (300 microM) was used to discriminate two previously identified classes of binding sites. Saturation isotherms and displacement curves constructed under different ionic conditions suggested that the effects of Cl- and Ca2+ could best be explained by postulating the existence of three major binding site populations in this preparation rather than two. The binding of L-glutamate to Glu A sites exhibits an absolute dependence on Cl-, and Ca2+ markedly increases the maximum density of these sites. Glu A sites bind quisqualate and 2-APB with relatively high affinity. Cl- (47 mM) more than doubles the maximum density of Glu B sites, but Ca2+ appears to have no effect. Glu B sites can be discriminated from the other classes by their relatively low affinity for quisqualate and 2-APB. There is reason to think that the Glu B population is heterogeneous. The novel Glu C population can be virtually selectively labeled by exposing 2-APB-sensitive binding sites to radioligand in Tris-HOAc buffer with Ca2+. Binding of L-[3H]glutamate to these sites is enhanced by both Cl- and Ca2+, but requires neither ion. Ca2+ appears to increase both the affinity of Glu C sites for L-glutamate and their maximum binding site density. In the presence of Ca2+ and Cl-, Glu C sites bind the radioligand with micromolar affinity (KD approximately 2 microM) and high capacity (Bmax approximately 160 pmol/mg protein).(ABSTRACT TRUNCATED AT 250 WORDS)

The sensitivity of opioid receptor types to regulation by sodium and GTP

The effects of Na+ and GTP on agonist binding to mu, delta, and kappa opioid binding sites in membranes from guinea pig cortex have been studied. All incubations were in a modified Krebs-Hepes buffer at 37 degrees; effects of Na+ were evaluated by replacement with an equal concentration of K+. mu binding sites appeared more sensitive than delta sites, while kappa sites were the least sensitive to both regulators. However, even at kappa sites, Na+ induced a significant reduction in agonist affinity and GTP caused a significant reduction in maximum binding.

Selective and reversible increase in the number of quisqualate-sensitive glutamate binding sites on hippocampal synaptic membranes after angular bundle kindling

The specific binding of L-[3H]glutamate to hippocampal synaptic membranes was examined in rats kindled by tetanic stimulation of the angular bundle. One day after the last of a minimum of 3 class 4 kindled seizures, the binding of L-[3H]glutamate to a quisqualate-sensitive site (GLU A) was about 40% greater than in electrode-implanted unstimulated controls. Saturation binding data indicated an increase in the maximum density of GLU A binding sites with no change in their affinity for L-glutamate. No such increase was detected 28 days after the last kindled seizure, although the animals were still kindled. Radioligand binding to a site that is much less sensitive to quisqualate (GLU B) was unaffected by kindling stimulation. These observations suggest that an increase in GLU A binding sites could be involved in the induction, but not in the maintenance, of the kindled state.

Evidence for differential localization of two binding sites for L-[3H]glutamate in rat fascia dentata

Two binding sites for L-[3H]glutamate were tentatively localized in rat fascia dentata by determining the effects of selective lesions on specific binding. Both destruction of dentate granule cells with colchicine and ablation of the ipsilateral entorhinal cortex markedly reduced radioligand binding to a quisqualate-sensitive site (GLU A), but only the entorhinal lesion significantly reduced binding to a site that is less sensitive to quisqualate (GLU B). These results suggest that GLU A binding sites are localized mainly on the dentate granule cells, whereas GLU B binding sites are localized, in part, on the perforant path fibers, but not on granule cells.

L-[3H]Glutamate binding to hippocampal synaptic membranes: two binding sites discriminated by their differing affinities for quisqualate

The excitatory glutamate analogs quisqualate and ibotenate were employed to distinguish multiple binding sites for L-[3H]glutamate on freshly prepared hippocampal synaptic membranes. The fraction of bound radioligand that was displaceable by 5 microM quisqualate was termed GLU A binding. That which persisted in the presence of 5 microM quisqualate, but was displaceable by 100 microM ibotenate, was termed GLU B binding. GLU A binding equilibrated within 5 min and remained unchanged for up to 80 min. GLU B binding appeared to equilibrate at least as rapidly, but incubation with ligand unmasked latent binding sites. Saturation binding curves were best fitted by single exponentials, which yielded KD values of about 200 nM (GLU A) and 1 microM (GLU B). On the average, GLU B binding sites were about twice as abundant in these membranes as were GLU A sites. Rapid freezing of the membranes, followed by storage at -26 degrees C and rapid thawing markedly diminished GLU A binding, but nearly tripled GLU B binding. Both site bound L-glutamate with 10-30 times the affinity of D-glutamate. The GLU A site also bound L-glutamate with about 10 times the affinity of L-aspartate and discriminated poorly between L- and D-aspartate. In contrast, the GLU B site bound L-aspartate with an affinity similar to that for L-glutamate, and with an order-of-magnitude greater affinity than D-aspartate. The structural specificities of the GLU A and GLU B binding sites suggest that these sites may correspond to receptors on hippocampal pyramidal cell dendrites that are activated by iontophoretically applied L-glutamate.

Complex binding of L-[3H]glutamate to hippocampal synaptic membranes in the absence of sodium

Specific binding of L-[3H]glutamate was investigated with a thoroughly washed synaptic membrane preparation from rat hippocampal formation, a region of brain densely innervated by putatively glutamatergic fibers. L-[3H]Glutamate bound rapidly, saturably, and reversibly to these membranes in the absence of Na+. Specific binding was greatest around 38 degrees C and at a slightly acidic pH. Saturation isotherms fit a model of two independent binding sites with dissociation constants of 11 and 570 nM and corresponding densities of 2.5 and 47 pmol/mg protein. All potent amino acid excitants, except N-methyl-D-aspartate and kainate, and several excitatory amino acid antagonists inhibited specific radioligand binding with IC50 values between 10(-7) M and 10(-4) M. In contrast, weak amino acid excitants and an inhibitor of glutamate uptake were nearly inactive. Displacement curves were analyzed with a computer program that assumed the simultaneous contributions of two independent sites at which each compound competitively inhibited the binding of L-[3H]glutamate. According to this analysis, ibotenate and the L- and D-isomers of glutamate and aspartate bind preferentially to the high-affinity site, whereas quisqualate, L-alpha-aminoadipate, and the L- and D-isomers of homocysteate bind preferentially to the low-affinity site. With the notable exception of gamma-D-glutamylglycine, all of the more potent antagonists appear to bind preferentially to the low-affinity site. Both sites exhibit marked stereoselectivity for L-glutamate. D- and L-Homocysteate and most excitatory amino acid antagonists increased specific binding at concentrations below those required to demonstrate inhibition. Some properties of the low-affinity binding site resemble those of junctional glutamate receptors on insect muscle, but neither site appears to correspond to the "N-methyl-D-aspartate receptor" or the "quisqualate receptor."