mu Opioid receptor-mediated G-protein activation by heroin metabolites: evidence for greater efficacy of 6-monoacetylmorphine compared with morphine.

The efficacy of heroin metabolites for the stimulation of mu opioid receptor-mediated G-protein activation was investigated using agonist-stimulated [(35)S]guanosine-5'-O-(gamma-thio)-triphosphate binding. In rat thalamic membranes, heroin and its primary metabolite, 6-monoacetylmorphine (6-MAM), were more efficacious than morphine or morphine-6-beta D-glucuronide. This increased efficacy was not due to increased action of heroin and 6-MAM at delta receptors, as determined by competitive antagonism by naloxone, lack of antagonism by naltrindole, and competitive partial antagonism with morphine. In agreement with this interpretation, the same relative efficacy profile of heroin and its metabolites was observed at the cloned human mu opioid receptor expressed in C6 glioma cells. Moreover, these efficacy differences were GDP-dependent in a manner consistent with accepted mechanisms of receptor-mediated G-protein activation. The activity of heroin was attributed to in vitro deacetylation to 6-MAM, as confirmed by HPLC analysis. These results indicate that the heroin metabolite 6-MAM possesses higher efficacy than other heroin metabolites at mu opioid receptors, which may contribute to the higher efficacy of heroin compared with morphine in certain behavioral paradigms in vivo.

Chronic intrathecal morphine administration produces homologous mu receptor/G-protein desensitization specifically in spinal cord.

Previous studies have shown that chronic i.v. treatment with morphine or heroin decreased mu opioid receptor activation of G-proteins in specific brain regions. The present study examined the effect of intrathecal (i.t.) morphine administration on receptor/G-protein coupling in the spinal cord. In spinal cord membranes, [35S]GTP gamma S binding was stimulated by agonists of several G-protein-coupled receptors, including mu opioid (DAMGO), delta opioid (DPDPE), GABA(B) (baclofen), cannabinoid CB(1) (WIN 55,212-2), muscarinic cholinergic (carbachol) and adenosine A(1) (PIA). [35S]GTP gamma S autoradiography revealed that most of this agonist activation of G-proteins was localized to laminae I and II of dorsal horn. To determine the effects of chronic morphine on these receptor activities, rats were treated for 7 days with 0.11 mg/kg/day i.t. morphine, and receptor activation of G-proteins was determined by [35S]GTP gamma S autoradiography of brain and spinal cord. In spinal cord sections, chronic morphine treatment decreased DAMGO-stimulated [35S]GTP gamma S binding in laminae I and II at all levels of spinal cord examined. There were no effects of morphine treatment on [35S]GTP gamma S stimulation in spinal cord by other receptor systems examined (Adenosine A(1) and GABA(B)), and no significant effects of chronic i.t. morphine treatment were observed in brain sections. These data show that homologous desensitization of mu receptor/G-protein coupling occurs specifically in spinal cord following chronic morphine administration.

Chronic heroin self-administration desensitizes mu opioid receptor-activated G-proteins in specific regions of rat brain.

In previous studies from our laboratory, chronic noncontingent morphine administration decreased mu opioid receptor-activated G-proteins in specific brainstem nuclei. In the present study, mu opioid receptor binding and receptor-activated G-proteins were examined after chronic heroin self-administration. Rats were trained to self-administer intravenous heroin for up to 39 d, achieving heroin intake up to 366 mg. kg(-1). d(-1). mu opioid-stimulated [(35)S]GTPgammaS and [(3)H]naloxone autoradiography were performed in adjacent brain sections. Agonist-stimulated [(35)S]GTPgammaS autoradiography also examined other G-protein-coupled receptors, including delta opioid, ORL-1, GABA(B), adenosine A(1), cannabinoid, and 5-HT(1A). In brains from heroin self-administering rats, decreased mu opioid-stimulated [(35)S]GTPgammaS binding was observed in periaqueductal gray, locus coeruleus, lateral parabrachial nucleus, and commissural nucleus tractus solitarius, as previously observed in chronic morphine-treated animals. In addition, decreased mu opioid-stimulated [(35)S]GTPgammaS binding was found in thalamus and amygdala after heroin self-administration. Despite this decrease in mu-activated G-proteins, [(3)H]naloxone binding demonstrated increased mu opioid receptor binding in several brain regions after heroin self-administration, and there was a significant decrease in mu receptor G-protein efficiency as expressed as a ratio between agonist-activated G-proteins and mu receptor binding. No effects on agonist-stimulated [(35)S]GTPgammaS binding were found for any other receptor examined. The effect of chronic heroin self-administration to decrease mu-stimulated [(35)S]GTPgammaS binding varied between regions and was highest in brainstem and lowest in the cortex and striatum. These results not only provide potential neuronal mechanisms that may contribute to opioid tolerance and dependence, but also may explain why various chronic effects of opioids develop to different degrees.

Sigma-2 receptors as a biomarker of proliferation in solid tumours.

Over the past several years, our group has provided considerable evidence that the expression of sigma-2 (sigma2) receptors may serve as a biomarker of tumour cell proliferation. In these in vitro studies, sigma2 receptors were expressed 8-10 times more in proliferative (P) tumour cells than in quiescent (Q) tumour cells, and the extent and kinetics of their expression were independent of a number of biological, physiological and environmental factors often found in solid tumours. Moreover, the expression of sigma2 receptors followed both the population growth kinetics when Q-cells were recruited into the P-cell compartment and the proliferative status of human breast tumour cells treated with cytostatic concentrations of tamoxifen. However, these in vitro studies may or may not be indicative of what might occur in solid tumours. In the present study, the sigma2 receptor P:Q ratio was determined for the cells from subcutaneous 66 (diploid) and 67 (aneuploid) tumours grown in female nude mice. The sigma2 receptor P:Q ratio of the 66 tumours was 10.6 compared to the sigma2 receptor P:Q ratio of 9.5 measured for the 66 tissue culture model. The sigma2 receptor P:Q ratio of the 67 tumours was 4.5 compared to the sigma2 receptor P:Q ratio of approximately equal 8 measured for the 67 tissue culture model. The agreement between the solid tumour and tissue culture data indicates that: (1) the expression of sigma2 receptors may be a reliable biomarker of the proliferative status of solid tumours and (2) radioligands with both high affinity and high selectivity for sigma2 receptors may have the potential to non-invasively assess the proliferative status of human solid tumours using imaging techniques such as positron emission tomography or single-photon emission computerized tomography.

Agonist-stimulated [35S]GTPgammaS binding in brain modulation by endogenous adenosine.

Coupling of receptors to G-proteins can be assessed by the ability of specific agonists to stimulate [35S]GTPgammaS binding in both brain membranes and sections in the presence of excess GDP. In some brain regions, however, high basal activity makes it difficult to detect agonist-stimulated [35S]GTPgammaS binding. The present study suggests a modification of the assay to reduce basal [35S]GTPgammaS binding and thus increase the signal:noise ratio. Adenosine A1 receptors belong to the class of G-protein-coupled receptors that activate Gi/Go proteins in brain. In the present study, the A1 agonist R(-)N6-(2-phenylisopropyl)adenosine (R-PIA) stimulated [35S]GTPgammaS binding in brain regions known to contain A1 receptors, including cerebellum, hippocampus and dentate gyrus, medial geniculate body, superior colliculus, certain thalamic nuclei, cerebral cortex, piriform cortex, caudate-putamen, and nucleus accumbens. Treatment of sections and membranes with adenosine deaminase (ADase), which is typically used in adenosine assays to eliminate endogenous adenosine, reduced basal [35S]GTPgammaS binding. In addition, for cannabinoid and mu-opioid agonists, the percent stimulation of [35S]GTPgammaS binding was approximately doubled when ADase was included in the assay. These results suggest that endogenous adenosine contributes significantly to basal [35S]GTPgammaS binding in certain brain regions, and that this activity may be reduced by the addition of ADase, thus improving the signal:noise ratio of agonist-stimulated [35S]GTPgammaS binding.

Effect of ploidy, recruitment, environmental factors, and tamoxifen treatment on the expression of sigma-2 receptors in proliferating and quiescent tumour cells.

Recently, we demonstrated that sigma-2 receptors may have the potential to be a biomarker of tumour cell proliferation (Mach et al (1997) Cancer Res 57: 156-161). If sigma-2 receptors were a biomarker of tumour cell proliferation, they would be amenable to detection by non-invasive imaging procedures, thus eliminating many of the problems associated with the flow cytometric measures of tumour cell proliferation presently used in the clinic. To be a good biomarker of tumour cell proliferation, the expression of sigma-2 receptors must be essentially independent of many of the biological, physiological, and/or environmental properties that are found in solid tumours. In the investigation reported here, the mouse mammary adenocarcinoma lines, 66 (diploid) and 67 (aneuploid), 9L rat brain tumour cells, and MCF-7 human breast tumour cells were used to study the extent and kinetics of expression of sigma-2 receptors in proliferative (P) and quiescent (Q) tumour cells as a function of species, cell type, ploidy, pH, nutrient depletion, metabolic state, recruitment from the Q-cell compartment to the P-cell compartment, and treatment with tamoxifen. In these experiments, the expression of sigma-2 receptors solely reflected the proliferative status of the tumour cells. None of the biological, physiological, or environmental properties that were investigated had a measurable effect on the expression of sigma-2 receptors in these model systems. Consequently, these data suggest that the proliferative status of tumours and normal tissues can be non-invasively assessed using radiolabelled ligands that selectively bind sigma-2 receptors.

Opioid inhibition of adenylyl cyclase in membranes from pertussis toxin-treated NG108-15 cells.

Gi/Go proteins are uncoupled from receptors by ADP-ribosylation with pertussis toxin (PTX). However, PTX treatment of delta opioid receptor-containing NG108-15 cells reduces, but does not eliminate, opioid inhibition of adenylyl cyclase. The present study explored potential mechanisms of this residual inhibition. Overnight treatment of NG108-15 cells with 100 ng/ml PTX eliminated both PTX-catalyzed [adenylyl-32P]NAD+-labeling of G proteins and agonist stimulation of low Km GTPase in membranes. Although PTX-treatment decreased the maximal opioid inhibition of adenylyl cyclase by 50-65%, the inhibition that remained was concentration-dependent and antagonist-reversible. This inhibition persisted in the absence of GTP (even though opioid inhibition of adenylyl cyclase in untreated membranes was GTP-dependent), but was eliminated by hydrolysis-resistant guanine nucleotide analogs, indicating that G-proteins were still involved in the coupling mechanism. However, assays of agonist-stimulated [35S]GTPgammaS binding in the presence of excess GDP indicated that PTX pretreatment eliminated stimulation of guanine nucleotide exchange by opioid agonists. These results suggest that in membranes from PTX-treated NG108-15 cells, a subpopulation of G proteins may transduce an inhibitory signal from agonist-bound opioid receptors without involvement of guanine nucleotide exchange.

Binding of aminoalkylindoles to noncannabinoid binding sites in NG108-15 cells.

1. Aminoalkylindoles, typified by WIN 55212-2, bind to G protein-coupled cannabinoid receptors in brain. Although cannabinoids inhibit adenylyl cyclase in NG108-15 neuroblastoma x glioma hybrid cells, cannabinoid receptor binding in these cells has not been described previously. This study compares pharmacological characteristics of [3H]WIN 55212-2 binding sites in rat cerebellar membranes and in NG108-15 membranes. 2. Although the KD of specified [3H]WIN 55212-2 binding was similar in brain and NG108-15 membranes, the Bmax was 10 times lower in NG108-15 than in cerebellar membranes. In both brain and NG108-15 membranes, aminoalkylindole analogues were relatively potent in displacing [3H]WIN 55212-2 binding. However, IC50 values for more traditional cannabinoids were significantly higher in NG108-15 membranes than in brain, e.g., the Ki values for CP55,940 were 1.2 nM in brain and > 5000nM in NG108-15 membranes. Moreover, sodium and GTP-gamma-S decreased [3H]WIN 55212-2 binding in brain but not in NG108-15 membranes. 3. These data suggest that WIN 55212-2 does not label traditional cannabinoid receptors in NG108-15 cells and that these novel aminoalkylindole binding sites are not coupled to G proteins.

Acute and chronic effects of opioids on delta and mu receptor activation of G proteins in NG108-15 and SK-N-SH cell membranes.

To compare activation of G proteins by opioid receptors, opioid agonist-stimulated guanosine 5'-O-(3-[35S]thiotriphosphate) ([35S]GTP gamma S) binding in the presence of excess GDP was assayed in membranes from NG108-15 (delta) and SK-N-SH (primarily mu) cells. Basal [35S]GTP gamma S binding consisted of a single class of low-affinity sites (KD 400-500 nM). Addition of agonists produced a high-affinity site 100-300-fold higher in affinity than the basal site. The receptor/transducer amplification factor (ratio of activated G protein Bmax to opioid receptor Bmax) was 10-fold higher for SK-N-SH mu receptors than for NG108-15 delta receptors. Chronic delta agonist ([D-Ser2]-Leu-enkephalin-Thr; DSLET) treatment of NG108-15 cells resulted in an 80% loss of DSLET-stimulated [35S]-GTP gamma S binding within 1 h. Morphine treatment of SK-N-SH cells decreased mu agonist ([D-Ala2, N-Me-Phe4,Gly5-ol]-enkephalin; DAMGO)-stimulated [35S]GTP gamma S binding by 45% after 16 h, with no effect after 1 h. Loss of agonist response was due to a decrease in the Bmax of activated G proteins with no change in the KD. These results provide a quantitative description of G protein activation occurring on acute and chronic exposure to opioid agonists.

Sigma 2 receptors as potential biomarkers of proliferation in breast cancer.

sigma 1 and sigma 2 receptors have been shown to exist in a number of rodent and human tumor cell lines. Although their expression is heterogeneous and their function is unknown, sigma receptors have been proposed as potential targets for diagnostic tumor-imaging agents. In this study, the density of sigma 2 receptors in proliferative (P) and quiescent (Q) cells of the mouse mammary adenocarcinoma, line 66, was examined. Scatchard analyses of sigma 2 receptors were performed on membrane preparations of 66 P cells from 3-day cultures and 66 Q cells from 7-, 10-, and 12-day cultures. The Scatchard studies revealed that 66 P cells had approximately 10 times more sigma 2 receptors/cell than the 66 Q cells from 10-day cultures. Although > 97% of the cells were quiescent after 7 days in culture, the maximum differential in the sigma 2 expression between 66 P and 66 Q cells was not attained until these cells had been in culture for 10 days. These data suggest that ligands labeled with positron-emitting or single photon-emitting radionuclides, which selectively bind sigma 2 receptors, have the potential to noninvasively assess the proliferative status of human breast tumors.

Role of cyclic AMP in the actions of cannabinoid receptors.

Cannabinoids, including delta 9-tetrahydrocannabinol (THC), bind to receptors that couple to Gi/o-proteins and inhibit adenylyl cyclase. However, like other G-protein-coupled receptors, cannabinoid receptors are also coupled to other effector systems. This review examines the characteristics of the cannabinoid-G-protein-adenylyl cyclase system, and explores the role of cyclic AMP in mediating effects of these drugs. Several conclusions emerge from this research. First, the principal actions of cannabinoids are mediated through G-protein-coupled receptors, and the intracellular signaling mechanism that initiates cellular response of cannabinoids is activation of G-proteins. Second, cannabinoid-inhibited adenylyl cyclase is only one of several different effectors coupled to these receptors, and different effectors may be used for different types of responses. Third, cannabinoid inhibition of adenylyl cyclase plays an important role in several aspects of cannabinoid function, including modulating conductance at a voltage-dependent K+ channel ("A" current) in the hippocampus, thus providing an effective rationale for behavioral effects of cannabinoids mediated in this region. Other functions of this system may include production of long-term changes in gene expression by inhibition of cyclic AMP response elements on strategic genes, and inhibition of anandamide synthesis, thus mediating some of the long-term effects of cannabinoids on neuronal function.

Role of cyclic AMP dependent protein kinase in cannabinoid receptor modulation of potassium "A-current" in cultured rat hippocampal neurons.

Cannabinoid receptor agonists have been previously shown to enhance a potassium A-current (IA) in cultured rat hippocampal neurons. This effect has been further demonstrated to be dependent on G-protein linkage to adenylyl cyclase and levels of intracellular cyclic AMP (cAMP). The present study extends this analysis to the involvement of cAMP-dependent protein kinase (PKA) in this cascade. Specific activators and inhibitors of PKA were shown to have differential effects on the voltage dependence of IA. Specific activators of PKA produced a negative shift in voltage dependence of IA, whereas PKA inhibitors produced a positive shift in IA voltage dependence, the latter similar to that effected by the cannabinoid agonist WIN 55,212-2. Although the negative shift in IA induced by PKA stimulation could be reversed by PKA inhibitors, the positive shift produced by the PKA inhibitors alone was only 50-60% of the cannabinoid-produced shift in IA voltage dependence. This partial effect of PKA inhibition was confirmed by biochemical assays in the same cultured neurons that showed a similar 50-60% decrement in in vitro protein phosphorylation produced by PKA inhibitors. Results are discussed in terms of a diffusible second messenger linkage of the cannabinoid receptor to the A-current channel via the role of protein phosphorylation in modulation of IA.

Modification of G protein-coupled functions by low-pH pretreatment of membranes from NG108-15 cells: increase in opioid agonist efficacy by decreased inactivation of G proteins.

Low-pH pretreatment increases opioid agonist efficacy in inhibiting adenylyl cyclase in brain membranes. The mechanism of this effect was examined in membranes from cultured NG108-15 cells. Pretreatment of NG108-15 membranes at pH 4.5 before assay at pH 7.4 produced the following modifications in G protein-mediated signal transduction: 1) decreased activation of adenylyl cyclase by Gs, 2) increased maximal inhibition of opioid agonist binding by sodium and by guanine nucleotides in the presence of sodium, and 3) increased maximal inhibition of adenylyl cyclase by agonists for G(i)-coupled receptors. These results are similar to those previously observed in rat brain membranes. The mechanism by which low-pH pretreatment increased receptor-mediated inhibition of adenylyl cyclase was investigated further by examining low-Km GTPase activity in low-pH-pretreated NG108-15 cell membranes. Low-pH pretreatment decreased basal and agonist-stimulated low-Km GTPase activity maximally in the absence of sodium and minimally in the presence of 120 mM NaCl. This change was due to a decrease in the Vmax of the enzyme, with no change in the Km for GTP, indicating that GTP hydrolysis was decreased without any decrease in the affinity of the G protein for GTP. Scatchard analysis revealed no decrease in the Bmax for high affinity opioid agonist binding, and Western blot analysis with a G(i)-specific antibody revealed no loss of G(i) protein, in low-pH-pretreated membranes. Moreover, concentration-effect curves for GTP in supporting opioid inhibition of adenylyl cyclase showed that low-pH pretreatment increased inhibition by the agonist only at GTP concentrations equal to or greater than the Km for GTP hydrolysis by the low-Km GTPase. Taken together, these results indicate that the efficacy of receptor-mediated inhibition of adenylyl cyclase can be increased by decreasing the maximal inactivation rate of G(i) subsequent to its activation by the receptor.

BW373U86: a nonpeptidic delta-opioid agonist with novel receptor-G protein-mediated actions in rat brain membranes and neuroblastoma cells.

BW373U86 is a potent and highly selective nonpeptidic agonist for delta-opioid receptors. To determine its ability to couple with G protein-linked second messenger systems, this study examined the effects of BW373U86 on the inhibition of adenylyl cyclase and the stimulation of low-Km GTPase activity. In rat striatal membranes, BW373U86 inhibited basal adenylyl cyclase activity in a GTP-dependent manner, with maximal inhibition levels similar to those of the prototypic delta agonist [D-Ser2,Thr6]Leu-enkephalin (DSLET). However, BW373U86 was approximately 100 times more potent than DSLET in inhibiting adenylyl cyclase. Analysis of the inhibitory activity across 10 brain regions revealed that both low and high concentrations of BW373U86 inhibited adenylyl cyclase activity in a manner similar to that of DSLET. Inhibition of adenylyl cyclase by BW373U86 was delta receptor selective, because the delta receptor-selective antagonist naltrindole was significantly more potent than naloxone and the mu receptor-selective antagonist D-Phe-Cys-Tyr-D-Trp-Orn-Thr-Pen-Thr-NH2 was ineffective in blocking BW373U86 inhibition. BW373U86 also inhibited adenylyl cyclase activity in membranes prepared from NG108-15 cells, with an IC50 value 5 times lower than that of DSLET. This increased potency was not observed in concentration-effect curves for agonist-stimulated low-Km GTPase in NG108-15 membranes. BW373U86 is a competitive inhibitor of [3H]diprenorphine at delta receptors of NG108-15 cell membranes. However, unlike DSLET, BW373U86 displacement of [3H]diprenorphine binding to NG108-15 cell membranes was not affected by sodium and guanine nucleotides. This lack of GTP effect on binding apparently produced slow dissociation rates for this agonist, because naltrindole was less potent in blocking BW373U86 inhibition of adenylyl cyclase when membranes were preincubated with this agonist. These results demonstrate the novel finding that the binding of a full agonist to a G protein-coupled receptor is not regulated by GTP, and they also show how the lack of regulation in receptor binding affects agonist potency.

Identification of cannabinoid receptors in cultures of rat cerebellar granule cells.

G protein-linked cannabinoid receptors are present in high density in cerebellum, where they inhibit adenylyl cyclase. This study explored whether cannabinoid receptors are co-localized with GABAB receptors on cerebellar granule cells. In rat cerebellar membranes, receptor-coupled G protein function was assayed by agonist stimulation of low Km GTPase as well as agonist-inhibited adenylyl cyclase. Addition of cannabinoid agonists together with the GABAB agonist, baclofen, produced additive responses with stimulation of low Km GTPase but only partially additive responses with inhibition of adenylyl cyclase. In Weaver and Staggerer but not Nervous mutant mice, cannabinoid-inhibited adenylyl cyclase was significantly decreased in cerebellar but not striatal membranes compared to littermate controls. In primary cultures of rat cerebellar granule cells, cannabinoids inhibited forskolin-stimulated cAMP levels, with IC50 values ranging from 0.1 to 2.0 microM. Cannabinoid inhibition of intracellular cAMP levels was blocked by pretreatment of cell cultures with pertussis toxin. Addition of baclofen and cannabinoid agonists together in cultured granule cells produced no additivity in response for inhibition of intracellular cAMP levels. These data confirm that G protein-linked cannabinoid receptors are present in cerebellar granule cells and may share adenylyl cyclase catalytic units with GABAB receptors.

Opioid and cannabinoid receptor inhibition of adenylyl cyclase in brain.

Both opioids and cannabinoids bind to G-protein-coupled receptors to inhibit adenylyl cyclase in neurons. These reactions were assayed in brain membranes, where maximal inhibitory activity occurred in the following regions: mu-opioid inhibition in rat thalamus, delta-opioid inhibition in rat striatum, kappa-opioid inhibition in guinea pig cerebellum, and cannabinoid inhibition in cerebellum. The inhibition of adenylyl cyclase by both cannabinoid and opioid agonists was typical of G-protein-linked receptors: they required GTP, they were not supported by non-hydrolyzable GTP analogs, and they were abolished (in primary neuronal cell culture) by pertussis toxin treatment. The immediate targets of this system were determined by assaying protein phosphorylation in the presence of receptor agonists and App(NH)p, a substrate for adenylyl cyclase. In striatal membranes, opioid agonists inhibited the phosphorylation of at least two bands of MW 85 and 63 kDa, which may be synapsins I and II, respectively. Other experiments determined the long-term effects of this second messenger system. In primary neuronal cultures, opioid-inhibited adenylyl cyclase attenuated forskolin-stimulated pro-enkephalin mRNA levels, thus providing a feedback regulation of opioid synthesis. Finally, in cerebellar granule cells, both cannabinoid and opioid receptors may exist on the same cells. In these cells, agonists which bind to different receptor types may produce similar biological responses.

Inhibition of protein phosphorylation by opioid-inhibited adenylyl cyclase in rat brain membranes.

Opioid inhibition of adenylyl cyclase is a major second messenger system associated with opioid receptors in brain. To identify membrane phosphoproteins whose phosphorylation state is modulated by opioid inhibition of adenylyl cyclase, rat striatal membranes were preincubated with opioid agonists in the presence of 500 microM 5'-adenylyl-imidodiphosphate (which acted as a substrate for adenylyl cyclase, but not for protein kinase) before addition of [gamma-32P]ATP. Under these conditions, adenylyl cyclase in the membranes formed cyclic AMP, which stimulated cyclic AMP-dependent protein kinase. This process was confirmed by observing forskolin-stimulated phosphorylation of two bands of MW 85 and 63 kDa, which were also stimulated directly by cyclic AMP. Forskolin-stimulated phosphorylation of these two bands was inhibited by 15 to 30% by opioid agonists such as D-Ala2-Met5-enkephalinamide. This inhibition of phosphorylation was mediated by opioid receptors, because it required both sodium and GTP, and was blocked by naloxone. These results suggest that these two proteins may be primary targets of opioid-inhibited adenylyl cyclase in striatal membranes.

A high-performance liquid chromatography assay of brain adenylate cyclase using [3H]ATP as substrate.

A sensitive, reproducible assay for adenylate cyclase is described which separates labeled cyclic AMP from ATP and other nucleotides by high-performance liquid chromatography (HPLC) on reverse-phase columns. The technique utilizes [3H]ATP as substrate, and the principal compound contaminating the [3H]cyclic AMP peak, adenosine, is removed by incubation of assay tubes with small amounts of adenosine deaminase. The HPLC elution utilizes high resolution (3 microns) short (10 cm) C-18 columns for increased resolution and decreased flow rates. Since cyclic AMP elutes at 4 min following injection, this procedure can easily process large numbers of samples per day when combined with automated techniques of sample injection and collection.

[125I]Tyr-bradykinin binding in primary rat brain cultures.

Kinins bind to specific, high affinity recognition sites in rat brain cell culture. Studies in these cultures minimize non-specific binding and degradation of the ligand. Binding of [125I]Tyr-bradykinin to intact cultured brain cells from neonatal rats was time- and pH-dependent. Scatchard analysis of saturation experiments yielded two affinity components with dissociation constant and maximum binding site concentration averaging 1 nM and 100 fmol/mg protein, and 16 nM and 1000 fmol/mg protein, respectively. The binding sites were specific for kinins and kinin analogues, and the order of potency in competing for [125I]Tyr-bradykinin binding was Lys-bradykinin greater than bradykinin greater than Tyr-bradykinin greater than Tyr8-bradykinin much much greater than Des-Arg9-bradykinin. Monovalent and divalent cations inhibited kinin binding. Comparison of competition curves performed in glial-enriched vs neuron-enriched cultures suggested that the kinin binding sites resided primarily on neurons. These data enhance the existing evidence suggesting kinins as neurotransmitters or neuromodulators.