Subcellular localization of a cytochrome P-450-dependent monogenase in vesicles of the higher plant Catharanthus roseus.

The intracellular location of a cytochrome P-450-dependent monoterpene hydroxylase from the higher plant, Catharanthus roseus, has been investigated. By differential and sucrose density gradient centrifugation, utilizing marker enzymes and electron microscopy, the monooxygenase was demonstrated to be associated with vesicles having a membrane thickness of 40-60 nm. The vesicles could be distinguished from endoplasmic reticulum, Golgi apparatus, mitochondria, and plasma membrane and were found in light membrane fractions containing provacuoles. Most definitive results were obtained when seedlings were ground in the presence of sand and in a medium containing sorbitol. Upon subjection of the 20,000-g pellet preparation to linear sucrose density gradient centrifugation, a threefold enrichment in hydroxylase activity was afforded in a yellow band having vesicles varying in size from 0.1 to 0.8 mum in diam and having a density of 1.09 to 1.10 g/cm3. Since the monooxygenase has been implicated in indole alkaloid biosynthesis in this plant, the data suggest the compartmentalization of at least a part of this pathway.

Accumulation of a tetrahydroisoquinoline in phenylketonuria.

3',4'-Deoxynorlaudanosolinecarboxylic acid (DNLCA), a tetrahydroisoquinoline derived from dopamine and phenylpyruvic acid, has been detected by computerized mass fragmentography in urine of phenylketonuric children and in urine and brain of rats with experimentally induced hyperphenylalaninemia. Levels of DNLCA in brain of treated animals were more than tenfold higher than controls, and the excess tetrahydroisoquinoline appeared to accumulate in the cerebellum and cortex. DNLCA is a noncompetitive inhibitor of dopamine beta-hydroxylase (inhibition constant, Ki, = 0.42 mM) and is taken up by the brain.

Overexpression of sigma receptors in nonneural human tumors.

Previous data indicated that opioid receptors occur in both neural and nonneural human tumors. However, it has recently been shown that some of the putative opioid binding may be attributable to sigma sites. In this study the occurrence of sigma and opioid receptors in nonneural human tumors was assessed. The neoplasms included renal and colon carcinomas and a sarcoma. [3H]1,3-di-o-tolylguanidine was used to assay sigma receptors by homologous competition binding assays, which when analyzed provided dissociation constant and receptor density values. Opioid binding was measured with [3H]-(-)-ethylketocyclazocine, a ligand which interacts with mu, delta, and kappa subtypes. Fresh surgical specimens were obtained from 9 human neoplasms, selected for their large size, and compared with nonmalignant tissues. All 9 tumors contained sigma sites, and dissociation constant values were within the range of 27-83 nM. Occasionally, two-site fit the data better than one-site binding, suggesting the presence of multiple sigma sites. Opioid binding was not detected. Intratumoral variability was evaluated by sampling several locations on the periphery of the mass and one in the center. Each of the samples was bisected, with a portion reserved for histological examination to correlate morphological features with receptor data. Changes in sigma binding were not associated with the extent of fibrosis, viability, or necrosis. Receptor density values displayed moderate intra- and intertumoral variation (coefficients of variation, 8-39 and 27-49%, respectively). More important, sigma binding in tumors was found to be greater than or equal to 2-fold higher than that of control nonmalignant tissue.

Evidence for transduction of mu but not kappa opioid modulation of extracellular signal-regulated kinase activity by G(z) and G(12) proteins.

Chronic treatment with micro or kappa opioid agonists (>/=2 h) inhibits EGF-induced ERK activation in opioid receptor overexpressing COS-7 cells. Although acute mu and kappa opioids activate ERK via a pertussis toxin-sensitive G protein, pertussis toxin insensitivity of the chronic mu (but not kappa) action was observed. Here, we tested several pertussis toxin-insensitive G proteins as candidates to transduce acute and/or chronic opioid modulation of ERK. Overexpressed Galpha(z) (but not Galpha(12)) transduced acute mu (but not kappa) ERK activation in pertussis toxin-treated COS-7 cells. Chronic mu (but not kappa) inhibited EGF stimulation of ERK in pertussis toxin-treated cells overexpressing Galpha(z) or Galpha(12). Transfection of Galpha(13) or Galpha(q) blocked inhibition under the same conditions. Overexpressed interfering and non-interfering Galpha(z) mutants differentially affected mu inhibition of ERK consistent with G(z) transduction. In this and prior studies, Galpha(z) and Galpha(12) immunoreactivity were detected in untransfected COS-7 cells, suggesting that these G proteins may be endogenous mediators of chronic mu inhibitory actions on ERK.

Tetrahydroisoquinolinecarboxylic acids and catecholamine metabolism in adrenal medulla explants.

In a study of the relationship of the tetrahydroisoquinolinecarboxylic acids (TIQCAs) to catecholamine metabolism, we have investigated their effects on cultured rat adrenal medulla explants. Medullae were incubated in medium containing norlaudanosolinecarboxylic acid (NLCA) or 3',4'-deoxynorlaudanosolinecarboxylic acid (DNLCA) (0.5 mM) in the presence and absence of [3H]tyrosine. By paired-ion reverse-phase high pressure liquid chromatography, tissue epinephrine (EPI), norepinephrine (NE), dopamine (DA) and TIQCA were resolved. Endogenous concentrations were measured with electrochemical detection, and radioactivity was assayed by collecting appropriate effluents. Tissue levels of the TIQCAs reached saturating levels of 0.36 mM by about 20 hr. DNLCA elicited a significant decrease (60%) in endogenous DA, NE and EPI at 40 hr, whereas only DA was depressed at 30 hr. NLCA had little effect after 30 or 40 hr. When tissues were maintained in the presence of alpha-methyltyrosine (0.5 mM) for 40 hr, catecholamine levels were depressed to an extent similar to that observed with DNLCA. Incubation with [3H]tyrosine in the presence of TIQCAs revealed inhibition of tyrosine uptake and suggested a reduction in the rate of catecholamine synthesis. These results are consistent with previous data on the inhibition of tyrosine 3-monooxygenase by DNLCA in vitro.

Tetrahydroisoquinolinecarboxylic acids and regulation of phenylethanolamine N-methyltransferase in cultured adrenal medulla.

Explants of rat adrenal medullae, cultured for up to 48 hr in the presence of 3',4'-deoxynorlaudanosolinecarboxylic acid (DNLCA) or alpha-methyltyrosine, exhibited a 69% increase in phenylethanolamine N-methyltransferase (PNMT) activity as measured in dialyzed homogenates. A related tetrahydroisoquinoline, norlaudanosolinecarboxylic acid (NLCA), when added to the medium did not elevate PNMT activity. No increase in the amount of PNMT was detected by immunochemical titration of homogenates from DNLCA-treated cultured medulla, nor were there changes in rates of synthesis or degradation of the enzyme. Although DNLCA is an inhibitor of tyrosine 3-monooxygenase, it had no effect on PNMT activity when added directly to an incubation mixture in vitro. Kinetic analyses of dialyzed homogenates from explants cultured in the presence of DNLCA revealed that the Vmax of PNMT was higher than that of control tissue. There was no decrease in Km after DNLCA treatment. The increase in PNMT activity appears to be a compensatory response to depletion of medullary catecholamines by DNLCA or alpha-methyltyrosine.

Opioid regulation of AP-1 DNA-binding activity in NG108-15 cells under conditions of opioid-receptor adaptation.

Opioid-receptor adaptation may lead to changes in transcriptional regulation by sequence-specific DNA-binding proteins. Gel-shift assays of nuclear extracts from NG108-15 cells revealed that an increase of AP-1 DNA-binding activity ensues under conditions previously established to induce down- or up-regulation of delta-opioid receptors.

A monoclonal anti-idiotypic antibody to mu and delta opioid receptors.

A mouse monoclonal, anti-idiotypic, anti-opioid receptor antibody (Ab2-AOR) has been generated from monoclonal anti-morphine antibodies (Ab1). Hybridoma culture supernatants were screened by a solid phase radioimmunoassay (RIA), based on their competition with radiolabelled morphine for Ab1. One of the Ab2s that gave a positive RIA also competed at rat brain opioid receptors with tritiated opioid ligands dihydromorphine (DHM), naloxone, etorphine, Tyr-D-Ala-Gly-Phe-D-Leu (DADLE), Tyr-D-Ala-Gly-NMe-Phe-Gly-ol (DAMGE) and Tyr-D-Pen-Gly-Phe-D-Pen (DPDPE). SDS-PAGE revealed Ab2-AOR to be highly purified after successive affinity and protein A-Sepharose chromatography. Ab2-AOR at concentrations of 10-100 nM competed with both mu- and delta-selective specific ligands for brain opioid receptors. Less than 13 micrograms/ml Ab2-AOR completely inhibited specific opioid radioligand binding to both soluble and membrane-bound opioid receptors. To demonstrate its anti-delta receptor activity further, a double-antibody ELISA procedure was developed that is based on the binding of Ab2-AOR to immobilized NG 108-15 cells (which contain only delta opioid receptors). Dose-dependent, opioid peptide- and opiate alkaloid-competitive binding of Ab2-AOR-containing ascites fluid to NG 108-15 cells was observed. A mu opioid agonist effect was demonstrated for Ab2-AOR, in that it decreased by 70% [3H]thymidine incorporation into DNA of fetal brain cell aggregates. This agonist-like action of Ab2-AOR was blocked by naltrexone. The antibody bound specifically to brain tissue sections and the presence of diprenorphine blocked this interaction. Hence, an Ab2 with mu and delta specificity has been characterized.

Desipramine modulation of sigma and opioid peptide receptor expression in glial cells.

Exposure of C6 glial cell cultures to desipramine induced the appearance of opioid receptors and up-regulated sigma receptors. Opioid binding was demonstrated with 3H-etorphine and 3H-dihydromorphine (DHM), but was not observed with the mu, delta and kappa ligands 3H-DAMGE, 3H-DADLE or 3H-(-)ethylketocyclazocine in the presence of specific blockers, respectively. Competition experiments with 3H-DHM and either (-)naloxone or (+)naloxone indicated the presence of authentic opioid receptors. In similar studies with beta-endorphin, its truncated form (1-27) or their N-acetyl derivatives, beta-endorphin proved to have the highest affinity. Opioid receptors in glial cell aggregates were primarily kappa, with few mu and delta sites. Desipramine increased Bmax values for kappa but not mu and delta.

Differential ontogeny of divalent cation effects on rat brain delta-, mu-, and kappa-opioid receptor binding.

The effect of the divalent cations, Mn2+, Mg2+ and Ca2+ on rat forebrain delta-, mu- and kappa-receptor binding was examined during postnatal development. It was found that delta-receptor binding, assessed with [3H]D-Ala2-D-Leu5-enkephalin ([3H]DADLE) (+ 10 nM D-Ala2- MePhe4-Gly-ol5-enkephalin (DAMGE)), was stimulated by the 3 cations in a dose- and developmental time-dependent manner. delta-Binding was most sensitive to the cations during the first week postnatal, prior to the appearance of high-affinity delta-binding. In contrast, inhibition of mu-receptor binding ([3H]DAMGE) by divalent cations appeared early in development and remained constant throughout the postnatal period. Divalent cation inhibition of kappa-binding ([3H]ethylketocyclazocine ([3H]EKC) + 100 nM DAMGE and 100 nM DADLE) appeared after the second week postnatal. These results demonstrate that the characteristics and postnatal development of divalent cation modulation of mu-, delta- and kappa-binding is distinctly different. Thus, the neonate may be a good model system to examine the binding properties and functions of delta- and kappa-receptor subtypes.

Differential postnatal development of mu and delta opiate receptors.

We found a differential postnatal development of mu and delta opiate receptors. Mu receptors labelled with low concentrations of [3H]naloxone appeared to develop earlier than did delta receptors labelled with [3H]D-Ala2-D-Leu5-enkephalin (0.5 nM). Competition binding studies also revealed a delayed appearance of delta receptors (day 12 postnatal).

Microsomal opiate receptors differ from synaptic membrane receptors in proteolytic sensitivity.

We have found that opiate receptors in smooth microsomal fractions differ from synaptic membrane-associated receptors in proteolytic sensitivity. With 3 proteases of different substrate specificities (trypsin, chymotrypsin and S. griseus protease) smooth microsomal opiate receptors from rat brain were consistently less sensitive to limited proteolysis than were synaptic membrane receptors. Thiamine pyrophosphatase, a luminal Golgi membrane marker enzyme, exhibited a similar resistance to S. griseus protease in microsomal preparations, while microsomal Na+/K+-ATPase (ouabain-sensitive) was readily destroyed by trypsin. We also discovered that smooth microsomal opiate receptors co-migrate with both Golgi membrane and endoplasmic reticulum marker proteins on equilibrium density gradients under isopycnic conditions. Electron microscopic examination of the Golgi-enriched fraction showed the typical cisternae frequently associated with isolated Golgi membranes. Synaptic junctions, presynaptic membranes, myelin and mitochondria were conspicuously absent from this fraction. Since the microsomes isolated in vitro showed similar topography to those in vivo, the binding sites for opiates could be localized on the luminal surface membranes of the microsomal fractions. The exquisite sensitivity of synaptic membrane opiate receptors to proteolysis suggests that these receptors are found on the extracellular surface of the synaptic junction.

Exogenous cholecystokinin (CCK) reduces neonatal rat brain opioid receptor density and CCK levels.

Newborn rats were given saline or cholecystokinin8 (CCK8) (5 micrograms/kg, twice daily) i.p. for 3 weeks. On day 21, effects on brain development were assessed. CCK-like immunoreactivity was measured in 7 brain regions; a small (12-18%) but significant decrease in endogenous levels of this peptide was detected in cerebral cortex, medulla and pons of the CCK-treated rats. Morphometric measurements revealed a slight reduction in thickness of most cerebral cortical sections within the CCK-treated group. The area of a midsagittal section of the cerebellum was unchanged except for the Purkinje/granule cell layer, which was smaller in CCK-treated animals. Levels of mu-, delta- and kappa-opioid receptors were estimated by homologous displacement binding assays using selective radioligands. The CCK treatment resulted in a significant decrease in levels of mu- (11%) and delta- (13%)-sites in the cerebral cortex. Neither binding affinities nor kappa-receptor densities were altered. Other animals received the same treatment regimens for 21 days and were maintained for an additional 29 days without treatment; these rats had reductions only in cortical mu-sites (15%). Chronic intraventricular administration of CCK (0.1 microgram/h) to adult rats did not elicit a similar down-regulation of cortical mu or delta receptors, suggesting that the effects observed in neonates reflected developmental processes.

Opioid receptor density changes in Alzheimer amygdala and putamen.

Since opioids can influence the release of acetylcholine, substance P and a number of other neurotransmitters that have been implicated in the pathogenesis of Alzheimer's disease (AD), it is of interest to assess opioid receptor levels in AD. We have examined mu, delta and kappa opioid receptor binding parameters, binding sensitivity to a GTP analog and distribution in amygdala, frontal cortex and putamen of AD brain. Control brains were matched according to age, sex, post-mortem interval and storage time. Kd values and GTP analog binding sensitivity did not differ in AD and control brains. Bmax values for mu ([3H]DAMGE) sites also appeared unaffected by in vitro binding assays. In contrast, kappa ([3H]U69593) and delta ([3H]DSLET) opioid receptor levels, were significantly changed. In AD amygdala kappa Bmax values increased from control levels of 123 +/- 12 to 168 +/- 13 fmol/mg protein, whereas densities of kappa and delta sites were decreased from 94 +/- 8 to 48 +/- 8 and 102 +/- 3.6 to 69 +/- 8.5 fmol/mg protein, respectively, in putamen. Autoradiography revealed corresponding differences in the distribution of kappa opioid receptors. The findings indicate that the kappa binding site, which is quantitatively the major opioid receptor class in human brain, undergoes marked changes in AD amygdala and putamen.

Demonstration of a slowly dissociating form of bovine hippocampal synaptic membrane opiate receptors.

We studied the binding characteristics of opiate receptors in synaptic plasma membranes isolated from bovine hippocampus. On the basis of kinetic binding studies the interaction of [3H][D-Ala2,D-Leu5]enkephalin (DADL) with its receptor was an extremely slow process. Rates of association and dissociation were determined and a pseudo-first order rate constant for association calculated to be 5.68 x 10(5) l/mol . s at 25 degrees C. The rate of dissociation (t 1/2 = 70 min) was accelerated by GTP and changed from linear to biphasic. The kinetically derived equilibrium dissociation constant (0.29 nM) was considerably lower than the KD obtained from Scatchard and Hill plots (1.24 nM). Measurement of DADL association as a function of temperature yielded a linear Arrhenius plot. Finally, competition binding assays revealed that delta-specific agonists exhibited relatively high potency in displacing [3H]DADL from synaptic plasma membranes receptors whereas mu-specific agonists and antagonists were less effective. These results with bovine hippocampus may be explained by the formation of a slow-dissociating, high affinity agonist conformation of the delta-opiate receptor which has been predicted for the system by the cyclic-allosteric and ternary complex models.

The prenatal development profile of expression of opioid peptides and receptors in the mouse brain.

Although the postnatal development of opioid systems of mammalian brain has been well studied, little is known about the ontogeny of and relationship between embryonic (E) opioid peptides and their receptors. Moreover, a simultaneous assessment of levels of the 3 classes of opioid peptides and their putative receptors during embryonal development has not been made. To this end, the ontogeny of opioid peptides and receptors in mouse brain were examined during the period E11.5 to postnatal day 1 (P1). Met-enkephalin, dynorphin and beta-endorphin immunoreactivity were detected before their putative opioid receptors. beta-Endorphin can be discerned as early as E11.5, whereas mu binding was first observed at E12.5. Although dynorphin and Met-enkephalin were measurable at the same time as beta-endorphin, kappa-receptors were not detected until E14.5 and delta sites were not found at all prenatally. Differences in immunoreactivity levels of the 3 peptides occur with dynorphin being lower than Met-enkephalin and beta-endorphin, consistent with a low Bmax for kappa binding. Expression of the 3 opioid peptides as well as mu and kappa opioid receptors rapidly increase in parallel from E14.5 to E18.5. Interestingly, levels of beta-endorphin diminish by P1, the stage at which a sharp rise of mu receptors occurs. In a comparative study of the binding of beta-endorphin 1-31, its truncated form (1-27) and their N-acetyl derivatives to E14.5 brain membranes, beta-endorphin 1-31 exhibited the highest affinity.

Cross-linking of [125I]beta-endorphin to mu-opioid receptors during development.

Radioiodinated human beta-endorphin was cross-linked to opioid receptors from rat brain membranes using the bifunctional reagents bis-[2-(succinimidooxycarbonyloxy)ethyl] sulfone (BSCOES) and disuccinimidyl suberate (DSS). Major radiolabeled bands migrated with Mr values of 65,000, 55,000 and 33,000, however the presence of the 55 kDa band was variable. The 65 kDa band was characterized as the mu-receptor: the binding of [125I]beta-endorphin to this band was displaced by mu-selective ligands and blocked by alkylation of the receptor by mu-specific, but not delta-specific alkylating agents. The cross-linked receptor underwent alterations in mol. wt. during development. Early in development, embryonic day 18 and postnatal day 1, the [125I]beta-endorphin-labeled material migrated as a single band of mol. wt. 55 kDa. By day 21 postnatally the higher mol. wt. band of 65 kDa was present, as was material of 53, 47 and 43 kDa. Although the protein labeled early in development migrated with a mol. wt. of 55 kDa similar to the delta-receptor isolated from NG108-15 neuroblastoma-glioma cells, competition studies suggest this protein is not the delta-receptor. The 65 kDa band, tentatively identified as the mu-receptor, was present in adults but not detected in neonates, despite competition binding data indicating the presence of mu-sites. The results suggest that the 55 kDa band found in the 1-day-old neonate may be an immature form of the mu-opioid receptor that undergoes posttranslational modification, perhaps glycosylation, during development.

Differential development of beta-endorphin and mu opioid binding sites in mouse brain.

Mouse brains of various ages from embryonal day 14 (E14) to adult were analyzed for opioid receptor binding using the enkephalin analog Tyr-D-Ala-Gly-NMe-Phe-Gly-ol (DAMGE) and the opiate alkaloid dihydromorphine (DHM) as mu-selective radioligands. Binding parameters were estimated from homologous and heterologous competition binding curves. During the postnatal period, Kd values for [3H]DAMGE did not change but Bmax values (fmol/mg protein) increased 2.7 fold from postnatal day 3 (P3) to P7. Minor receptor density fluctuations were evident from P7 to adult. Similar results were obtained with [3H]DHM. In contrast, estimation of total mu binding sites (fmol/brain) revealed a continuous rise from P3 to the adult. The postnatal developmental profile of total mu binding sites was comparable to the weight gain of mouse brain and the increase in protein content. In contrast, during the same period beta-endorphin immunoreactivity (IR) levels undergo an increase that is inversely proportional to mu opioid receptor Bmax values. [3H]DAMGE binding to E14 membrane preparations was inhibited to a greater extent by Gpp(NH)p than that to P1 or adult. Additional characterization of mu receptors was accomplished by heterologous competition binding assays. IC50 values for beta-endorphin in competition with [3H]DHM and [3H]DAMGE were age dependent and differed for the two radioligands. These results suggest that mu receptor selectivity for mu-specific peptide and alkaloid ligands changes as a function of age.

Brain opioid receptor adaptation and expression after prenatal exposure to buprenorphine.

Previous in vivo studies revealed that buprenorphine can down-regulate mu and up-regulate delta2 and kappa1 opioid receptors in adult and neonatal rat brain. To assess gestational effects of buprenorphine on offspring, pregnant rats were also administered this drug and opioid receptor binding parameters (Kd and Bmax values) were measured by homologous binding assays of postnatal day 1 (P1) brain membranes. Buprenorphine concentrations of 2.5 mg/kg injected into dams elicited an up-regulation of kappa1 opioid receptors as detected with the kappa1-selective agonist 3H-U69593. Parallel studies with the mu-selective agonist [D-ala2, mephe4,gly-ol5] enkephalin revealed a buprenorphine-induced down-regulation in receptor density at 0.3, 0.6 or 2.5 mg/kg drug treatment. A greater down-regulation of mu receptors for P1 males than for their female counterparts was observed. Buprenorphine did not cause a reduction in binding affinity in these experiments. Changes in opioid receptor adaptation induced by buprenorphine were further supported by data from cross-linking of 125I-beta-endorphin to brain membrane preparations. RT-PCR analysis of opioid receptor expression was also estimated in P1 brains. However, significant changes in neither mu nor kappa receptor message were detected in P1 brains as a result of prenatal buprenorphine treatment under the conditions of these experiments. Since buprenorphine is being evaluated in clinical trials for the treatment of heroin abuse, the in utero actions of the drug have ramifications for its use in the treatment of maternal drug abuse.

Transient down-regulation of neonatal rat brain mu-opioid receptors upon in utero exposure to buprenorphine.

Gestational actions of the mixed agonist-antagonist buprenorphine on mu- and kappa 1-opioid binding in neonatal and maternal rat brain were investigated. Upon exposure of pregnant rats to 0.5 mg/kg buprenorphine for 7 days prior to birth, postnatal day-one (P1) and P7 offspring brain mu-binding parameters (Kd and Bmax) were assessed with 3H-labeled [D-Ala2,Mephe4,Gly-ol5] enkephalin (DAMAGE). DAMAGE binding was attenuated by 64% in P1 membranes, whereas P7 preparations showed no changes. The same buprenorphine regimen resulted in diminished DAMGE Bmax values in mothers' brains, 2 but not 7 days after cessation of drug administration. Receptor density changes were not accompanied by alteration of mu-binding affinities. Although the postnatal developmental profile of kappa 1 opioid receptors in rat brain measured with [3H]U69593 revealed the presence of an ample number of sites for detection, their binding parameters in P1, P7 pups and mothers were unaffected by 0.5 mg/kg buprenorphine. In summary, buprenorphine administration to pregnant rats transiently down-regulates mu opioid receptors in neonatal and maternal brain.