Carboxyl terminal peptides derived from prepro-orphanin FQ/nociceptin (ppOFQ/N) are produced in the hypothalamus and possess analgesic bioactivities.

Orphanin FQ/nociceptin (OFQ/N), the endogenous ligand for the ORL-1/KOR-3 receptor, produces a wide variety of behavioral responses. Its precursor protein, prepro-OFQ/N (ppOFQ/N) contains several series of amino acids bounded by pairs of basic amino acids, raising the possibility that additional functional neuropeptides could be generated by proteolytic posttranslational processing. Several of these processing products have been shown to have pharmacological activity, including the 17 amino acid peptide OFQ/N (mppOFQ/N(140-157)) which is a major product of this precursor in the hypothalamus. Here we have used a newly developed radioimmunoassay and RP-HPLC to detect mppOFQ/N(160-187) in mouse hypothalamic extracts. Murine ppOFQ/N(160-187) has potent analgesic activity supraspinally (3.4 nmol, i.c.v.) and spinally (4.3 nmol, i.t.). This analgesic activity was reversed by the opioid antagonist naloxone (5 mg/kg, s.c.) and kappa(1)-selective opioid antagonist nor-BNI (60 microg, i.c.v.), despite the inability of ppOFQ/N(160-187) to compete binding in mu, delta, kappa(1), kappa(3), or OFQ/N binding assays. These findings suggest that murine ppOFQ/N(160-187) may be a physiologically relevant neuropeptide with a novel mechanism of action.

Orphanin FQ/nociceptin and naloxone benzoylhydrazone activate distinct receptors in BE(2)-C human neuroblastoma cells.

kappa(3) opioid receptors have a unique binding and analgesic profile, as originally defined by naloxone benzoylhydrazone (NalBzoH). Although antisense studies demonstrated the close relationship between kappa(3) opioid and Orphan opioid receptor-like receptor (ORL1) and implied they were generated from the same gene, these studies also revealed differences in the sensitivity profiles of NalBzoH and orphanin FQ/nociceptin (OFQ/N), indicating that they were not identical. To help define the relationship between kappa(3) and ORL1 receptors, we utilized BE(2)-C human neuroblastoma cells that natively express functional ORL1 and kappa(3) opioid receptors. (125)I-[Tyr(14)]OFQ/N binds to a single population of receptors in BE(2)-C cells. Competition binding and adenylyl cyclase studies clearly illustrated marked selectivity differences between the ORL1 and the kappa(3) sites. Furthermore, antisense DNA targeting ORL1 blocked the inhibition of cAMP by OFQ/N, but not by NalBzoH. Thus, the receptor mechanisms mediating the activity of OFQ/N and NalBzoH in BE(2)-C cells are distinct.

Morphine and morphine-6beta-glucuronide-induced feeding are differentially reduced by G-protein alpha-subunit antisense probes in rats.

Although morphine and its active metabolite, morphine-6beta-glucuronide (M6G), each induce mu-opioid receptor-sensitive feeding, different antisense oligodeoxynucleotide (AS ODN) probes directed against the MOR-1 clone produce distinct effects. Thus, MOR-1 AS ODN probes directed against exons 1 or 4 reduce morphine-, but not M6G-induced feeding, whereas probes directed against exons 2 or 3 reduce M6G-, but not morphine-induced feeding. AS ODN probes directed against different G-protein alpha-subunits differentially reduced morphine (G(ialpha2)) and M6G (G(ialpha1))-induced analgesia. The present study evaluated the ability of AS ODN probes directed against G-protein alpha-subunits to reduce feeding induced by morphine and M6G in rats. The AS ODN probes (25 microg, i.c.v.) were administered once 24 h prior to morphine (5 microg, i.c.v.) or M6G (250 ng) and spontaneous free feeding was assessed 1, 2 and 4 h thereafter. In agreement with analgesic studies, morphine-induced feeding was significantly reduced by the G(ialpha2) AS ODN probe. Morphine-induced feeding was unaffected by AS ODN probes directed against either G(ialpha1), G(ialpha3), G(oalpha), G(x/zalpha), G(qalpha) or a nonsense control probe, and was significantly enhanced by pretreatment with the G(salpha) probe. In contrast, M6G-induced feeding was significantly reduced by AS ODN probes directed against either G(ialpha1), G(ialpha3) or G(x/zalpha), whereas AS ODN probes targeting G(ialpha2), G(oalpha), G(salpha), G(qalpha) or a nonsense control probe were ineffective. When M6G-induced feeding was assessed at a dose (500 ng) which was sensitive to MOR-1 AS ODN effects, none of the G-protein alpha-subunit AS ODN probes were effective. These data indicate that morphine and M6G-induced feeding are mediated through different G-protein alpha-subunits, and provide further evidence for separate and distinct molecular mechanisms mediating these functional responses through different opioid receptors. This strongly suggests that M6G may act through a novel opioid receptor displaying a distinct pharmacological mechanism.

Autoradiographic localization of (125)I[Tyr(14)]orphanin FQ/nociceptin and (125)I[Tyr(10)]orphanin FQ/nociceptin(1-11) binding sites in rat brain.

The endogenous ligand for the orphan opioid receptor, orphanin FQ/nociceptin (OFQ), has recently been characterized. The OFQ peptide sequence contains paired basic amino acids, suggesting the possibility of posttranslational processing to a peptide containing the first 11 amino acids of the OFQ peptide. This peptide has been reported in the brain and it has a unique pharmacology. In the present study, we compared the autoradiographic distribution of (125)I[Tyr(14)]OFQ and (125)I[Tyr(10)]OFQ(1-11) in coronal rat brain sections. Nonspecific binding was defined with unlabeled OFQ or OFQ(1-11), respectively. Both radioligands demonstrated high levels of specific binding (>95% of total binding), with no appreciable binding in white matter areas with either ligand. (125)I[Tyr(14)]OFQ binding was widely distributed throughout the rat brain. In contrast, (125)I[Tyr(10)]OFQ(1-11) binding was more restricted. The highest (125)I[Tyr(14)]OFQ binding levels measured in this study were found in the locus coeruleus, an area which contained very low (125)I[Tyr(10)]OFQ(1-11) binding. Both ligands labeled the cortex, hippocampus and amygdala. In the thalamus, (125)I[Tyr(14)]OFQ binding was prominent in most nuclei, whereas (125)I[Tyr(10)]OFQ(1-11) binding was restricted to the midline thalamus. (125)I[Tyr(14)]OFQ binding was heavy in the suprachiasmatic hypothalamus, and moderate in other hypothalamic nuclei. (125)I[Tyr(10)]OFQ(1-11) binding in the hypothalamus, however, was present mainly in the ventromedial hypothalamic nucleus. Lower binding levels of both ligands were found in the caudate putamen. The distinct autoradiographic patterns of these two ligands are consistent with different binding sites, which might help explain their different functional activities.

Identification of a high-affinity orphanin FQ/nociceptin(1-11) binding site in mouse brain.

The presence of pairs of basic amino acids within the orphanin FQ/Nociceptin (OFQ/N) sequence has raised the possibility that truncated versions of the peptide might be physiologically important. OFQ/N(1-11) is pharmacologically active in mice, despite its poor affinity in binding assays (K(i) > 250 nM) for the OFQ/N receptor. Using an analog of OFQ/N(1-11), [(125)I][Tyr(10)]OFQ/N(1-11), we identified a high-affinity binding site (K(D) 234 pM; B(max) 43 fmol/mg protein) with a selectivity profile distinct from the OFQ/N receptor and all the traditional opioid receptors. This site had very high affinity for OFQ/N and its related peptides. The most striking differences between the new site and the OFQ/N receptor previously observed in brain were seen with traditional opioids. Dynorphin A analogs and alpha-neoendorphin competed with [(125)I][Tyr(10)]OFQ/N(1-11) binding in mouse brain with K(i) values below 10 nM, while naloxone benzoylhydrazone (K(i) 3.9 nM) labeled the [(125)I][Tyr(10)]OFQ/N(1-11) binding site as potently as many traditional opioid receptors. Several other opioids, including fentanyl, (-)cyclazocine, levallorphan, naltrindole, and diprenorphine, also displayed moderate affinities for this site. Finally, the [(125)I][Tyr(10)]OFQ/N(1-11) site had a unique regional distribution consistent with a distinct receptor. Thus, [(125)I][Tyr(10)]OFQ/N(1-11) labels a novel site in brain with a selectivity profile intermediate between that of either opioid or OFQ/N receptors.

Antinociceptive analogs of orphanin FQ/nociceptin(1-11).

The presence of pairs of basic amino acids within the sequence of orphanin FQ/nociceptin (OFQ/N) peptide, the endogenous ligand for the ORL1/KOR-3 receptor, has raised the possibility that processing might generate pharmacologically important truncated peptides, including OFQ/N(1-11). OFQ/N(1-11) is pharmacologically active in vivo with a potency comparable to OFQ/N. Several tyrosine-containing analogs of OFQ/N(1-11) have been synthesized and examined for antinociceptive activity. Like OFQ/N(1-11), [Tyr1]OFQ/N(1-11), [Tyr10]OFQ/N(1-11) and [IodoTyr10]OFQ/N(1-11) given supraspinally in mice were antinociceptive in the tailflick assay in mice. The tyrosine analogs showed similar potencies as OFQ/N(1-11) but longer durations of action. This response was readily reversed by the opioid antagonist naloxone despite poor affinities for these analogs at opioid receptors. Another compound, [Tyr11]OFQ/N(1-11) was highly epileptogenic, inducing naloxone-sensitive seizures in greater than 50% of the mice tested at doses comparable to those examined with the other analogs. These results indicate that it is possible to make analgesic OFQ/N(1-11) analogs. The activity of [IodoTyr10]OFQ/N(1-11) suggests that it may prove useful as a radioligand in exploring potential OFQ/N(1-11) binding sites.

Pharmacological characterization of endomorphin-1 and endomorphin-2 in mouse brain.

The recently isolated peptides endomorphin-1 and endomorphin-2 have been suggested to be the endogenous ligands for the mu receptor. In traditional opioid receptor binding assays in mouse brain homogenates, both endomorphin-1 and endomorphin-2 competed both mu1 and mu2 receptor sites quite potently. Neither compound had appreciable affinity for either delta or kappa1 receptors, confirming an earlier report. However, the two endomorphins displayed reasonable affinities for kappa3 binding sites, with Ki values between 20 and 30 nM. Both endomorphins competed 3H-[D-Ala2, MePhe4,Gly(ol)5] enkephalin binding to MOR-1 receptors expressed in CHO cells with high affinity. In mouse brain homogenates 125I-endomorphin-1 and 125I-endomorphin-2 binding was selectively competed by mu ligands. 125I-Endomorphin-1 and 125I-endomorphin-2 also labeled MOR-1 receptors expressed in CHO cells with high affinity. Autoradiography of the two 125I-labeled endomorphins demonstrated regional patterns in the brain similar to those previously observed for mu drugs. Pharmacologically, the endomorphins were potent analgesics. Although they were equipotent supraspinally, endomorphin-1 was more potent spinally. Endomorphin analgesia was effectively blocked by naloxone, as well as the mu-selective antagonists beta-funaltrexamine and naloxonazine. In CXBK mice, which are insensitive to supraspinal morphine, neither endomorphin was active, consistent with a mu mechanism of action. Finally, the endomorphins inhibited gastrointestinal transit. In conclusion, these results support the mu selectivity of these agents.

Orphan opioid receptor antisense probes block orphanin FQ-induced hyperphagia.

Orphanin FQ/nociceptin binds with high affinity to the orphan opioid receptor-like/K-3 (ORL1/KOR-3) clone, and stimulates feeding. The present study demonstrated that antisense oligodeoxynucleotides directed against either exons 1, 2 or 3 of the ORL1/KOR-3 clone reduced orphanin FQ/nociceptin-induced hyperphagia. A missense probe was ineffective. Naltrexone dose-dependently reduced orphanin FQ/nociceptin-induced hyperphagia. These data suggest that the receptor responsible for orphanin FQ/nociceptin-induced hyperphagia is encoded by the ORL1/KOR-3 clone.

Analgesic activity of orphanin FQ2, murine prepro-orphanin FQ141-157 in mice.

Orphanin FQ/nociceptin (OFQ/N) is generated from a larger precursor peptide, prepro-orphanin FQ (ppOFQ). Within the sequence of murine ppOFQ is another putative heptadecapeptide, orphanin FQ2 (OFQ2), corresponding to murine ppOFQ141-157. OFQ2 was a potent analgesic given either supraspinally (ED50 0.5 microgram, i.c.v.) or spinally (ED50 0.7 microgram, i.t.). As with opioids and OFQ/N, OFQ2 analgesia was enhanced by blockade of sigma receptors with haloperidol, which increased the potency of the peptide over 10-fold. Supraspinal OFQ2 analgesia was readily reversed by naloxone, implying that it activated opioid systems. Spinal OFQ2 analgesia was insensitive to naloxone. OFQ2 also inhibited gastrointestinal transit. Together, these studies suggest that OFQ2 may be a relevant neuropeptide with important physiological actions.

Biochemical evidence for orphanin FQ/nociceptin receptor heterogeneity in mouse brain.

A recently identified novel peptide, orphanin FQ/nociceptin (OFQ/N), is an endogenous ligand for a unique member of the cloned opioid receptor family. Saturation studies in mouse brain membranes reveal curvilinear Scatchard plots with both a higher (KD 3.8 pM, Bmax 31.6 fmol/mg protein) and a lower (KD 896 pM, Bmax 233 fmol/mg protein) affinity site in brain tissue, compared to only a single site in transfected CHO cells (KD 36 pM). Competition studies confirm the high affinity of OFQ/N for this site, but shallow Hill slopes suggest heterogeneity. Traditional opioids have poor affinity for this receptor and OFQ/N and its fragments do not label traditional opioid receptors. In brain homogenates, both OFQ/N and OFQ/N(1-11) inhibit forskolin-stimulated camp accumulation with IC50 values of 1 nM or less, an action which is readily reversed by opioid antagonists. OFQ/N(1-7) shows little activity. Together, these studies suggest the presence of heterogeneous, functionally active OFQ/N receptors in mouse brain.

Processing site blockade results in more efficient conversion of proenkephalin to active opioid peptides.

Prohormones are known to be processed at various cleavage sites in a defined temporal order, suggesting the possibility of sequential unfolding of processing sites. In order to investigate whether sequential processing at predefined sites is in fact required for proper processing, site-directed mutagenesis was performed to block known initial cleavage sites within proenkephalin. Pulse-chase/immunoprecipitation experiments were employed to analyze the fate of mutant and native proenkephalins in stably transfected AtT-20 cells. While processing did not occur at blockaded sites, surprisingly, overall processing of mutant proenkephalins proceeded efficiently, and alternative sites were chosen. When compared with native proenkephalin, processing of mutant proenkephalins occurred more slowly at early stages and more quickly at later stages. Experiments employing endoglycosidase H indicated that the early slow processing of mutant proenkephalins may be due to delays in intracellular transport. Metabolic labeling studies showed that more efficient production of bioactive opioids occurred in all processing site blockade mutants examined; these results were confirmed using several different radioimmunoassays of stored peptide products. We conclude that efficient processing of prohormone precursors does not require a specific temporal order of processing events. The fact that mutant proenkephalins were more fully processed than native proenkephalin may provide a route for more efficient production of opioid peptides in applications for chronic pain treatment.

Role of PC2 in proenkephalin processing: antisense and overexpression studies.

The contribution of the prohormone-processing enzyme PC2 to the proteolytic maturation of proenkephalin was examined in three sets of studies. In the first, the processing of this precursor was compared in PC2-rich (Rin5f) and PC2-lacking (AtT-20) cell lines expressing proenkephalin by virtue of stable transfection. These studies showed that the time frame for processing of this precursor is cell line specific, with AtT-20 cells processing proenkephalin to peptide B much more rapidly than Rin cells. However, the latter cell line processed proenkephalin much more extensively, i.e., produced a greater proportion of the penta- to octapeptide enkephalins. The involvement of PC2 in these later processing events was analyzed by examining the processing of proenkephalin in PC2-overexpressing AtT-20 cell lines. These experiments yielded a processing profile similar to that observed for Rin cells, although the time frame of initial processing was similar to that found in AtT-20 cells. To confirm the physiological involvement of proenkephalin in the production of the small opioid peptides, we generated a Rin cell line in which the production of PC2 was impaired due to stable expression of antisense mRNA to this enzyme. These experiments provided conclusive evidence that the generation of Met-enkephalin-Arg-Phe and Met-enkephalin-Arg-Gly-Leu, but not the larger enkephalin-containing peptides, is mediated by PC2. Taken together, our data support the idea that PC2 is physiologically capable of mediating only the later processing steps of neuropeptide precursors. PC2 thus appears to be the primary enzyme responsible for the generation of bioactive opioid peptide species from proenkephalin.

Characterizing kappa3 opioid receptors with a selective monoclonal antibody.

To help characterize kappa3 receptors and establish their relationship to traditional mu and delta receptors, we have generated a kappa3-selective monoclonal antibody. Monoclonal antibodies were raised against BE(2)-C cells, a human neuroblastoma cell line containing mu, kappa3, and delta opioid receptors. Of the 5,000 hybridoma cell lines screened, approximately 2,000 hybridomas tested positive against BE(2)-C membranes by ELISA, but only 98 of these were negative against a different neuroblastoma cell line lacking opioid receptors. Supernatants from one hybridoma, 8D8, inhibited up to 90% of 3H-NalBzoH (kappa3) binding without affecting 3H-DAMGO (mu) or 3H-naltrindole (delta) binding in BE(2)-C membranes. The selectivity of the antibody was further demonstrated by its blockade of the inhibition of cAMP accumulation in BE(2)-C cells by the kappa3 agonist NalBzoH but not the mu agonist morphine. Monoclonal antibody 8D8 (mAb8D8) also recognizes kappa3 receptors from mouse, rat, and calf brain. Administered intracerebroventricularly, mAb8D8 blocked kappa3 but not morphine (mu) analgesia in vivo. On Western blots, mAb8D8 recognized a protein with a molecular mass of approximately 70 kilodaltons in BE(2)-C. These studies demonstrate the selectivity of mAb8D8 for kappa3 receptors and provide additional support for the existence of this unique opioid receptor subtype.

Differential processing of proenkephalin by prohormone convertases 1(3) and 2 and furin.

Recombinant vaccinia virus vectors were used to coexpress mouse prohormone convertase 1 (mPC1), mPC2, or human furin together with human proenkephalin in GH4C1 cells (rat pituitary somatomammotrophs) to examine the proteolytic processing of proenkephalin by these enzymes. Radioimmunoassays performed on high pressure gel permeation size-fractionated extracts obtained from GH4C1 cells and corresponding conditioned media revealed distinct profiles of immunoreactivity for products generated by each enzyme. PC1 produced intermediate sized processing products (3-10 kDa); the major immunoreactive enkephalin-containing species observed eluted at the positions of peptide B, the 5.3-kDa fragment, and free Leu5-enkephalin. PC2 exhibited a more complete processing profile. The major immunoreactive enkephalins produced were free Met5-enkephalin-Arg-Phe, free Met5-enkephalin-Arg-Gly-Leu, free Leu5-enkephalin, and free Met5-enkephalin. Thus PC2 appears to be more capable of generating active opioid units from proenkephalin than is PC1. Finally, furin cleaved proenkephalin to generate peptide B, an unidentified peak between the 18- and 5.3-kDa fragments, and a small amount of the 5.3-kDa fragment. Radiosequencing data verified that the production of the 5.3-kDa fragment by PC1 occurred as a result of a Lys-Lys cleavage. The ability of PC1 to cleave proenkephalin (but not proopiomelanocortin) at a Lys-Lys site implies that the structural context of the paired basic cleavage site may be more important in the determination of cleavage specificity than the particular pair of basic residues at the site.

Immunocytochemical localization of the neuropeptide-synthesizing enzyme PC1 in AtT-20 cells.

The subtilisin-like enzyme PC1 (also known as PC3) cleaves the neuropeptide precursor proopiomelanocortin at paired basic residues in transfection experiments, thus providing evidence for a critical role in precursor processing. While mRNA for this enzyme is highly enriched in neuroendocrine tissues, little is known about the tissue and subcellular distribution of the PC1 protein. This study used immunocytochemical techniques to investigate the anatomical distribution of PC1, both alone and compared to met-enkephalin (MET-enk), in AtT-20 pituicytes transfected with proenkephalin cDNA. A high density of PC1 immunostaining was observed in a small region adjacent to the nucleus and in the tips of the processes of these cells. Dual-staining immunocytochemistry of whole cells illustrated that both PC1 and MET-enk immunoreactivity were present in the tips, but PC1 was concentrated in a region adjacent to the nucleus while MET-enk punctate staining was dispersed throughout the soma. This codistribution was confirmed in semithin sections of dual-stained cells cut at 1-1.5 microns through the thickness of the cells. PC1 staining resembled that of TGN38, a marker for the trans-Golgi network. When PC1 immunocytochemistry was performed in cells that were pretreated with brefeldin A, a drug that redistributes the proximal Golgi compartments to the endoplasmic reticulum, there was a complete disruption of the defined locus of PC1 immunoreactivity. Taken together, our data indicate that (1) PC1 is concentrated in a region of the cell body resembling the trans-Golgi network and (2) both the enzyme and the processed peptide are transported to the tips of the processes.(ABSTRACT TRUNCATED AT 250 WORDS)

Posttranslational processing of proenkephalin in AtT-20 cells: evidence for cleavage at a Lys-Lys site.

Proteolytic processing of proenkephalin was examined in several subclones of AtT-20 cells stably transfected with rat proenkephalin cDNA (AT/PE cells). Proenkephalin is synthesized in both N-glycosylated and unglycosylated forms, as demonstrated by treatment with tunicamycin. RIAs and Western blot studies showed that AT/PE clones process proenkephalin at some, but not all, Lys-Arg sequences in a limited processing profile reminiscent of bovine adrenal chromaffin cells. Pulse-chase studies using Met5-enkephalin-Arg-Gly-Leu antiserum demonstrated that 50% of the precursor is processed within 1 h, and processing is complete after 2.5 h with the production of the 5.3-kilodalton (kDa) peptide. Further cleavage to the octapeptide Met5-enkephalin-Arg-Gly-Leu is minimal. Radiosequencing results verified the efficient cleavage of a Lys-Lys site within proenkephalin that resulted in the production of the 5.3-kDa peptide. Proenkephalin cleavage products stored within cells, which included the 5.3-kDa peptide, could be released upon stimulation of cells with BaCl2 (2-fold above basal levels), 8-bromo-cAMP or CRF (7- and 8-fold above basal levels, respectively), and a mixture of BaCl2 and 8-bromo-cAMP (20-fold above basal levels). An important difference between the processing of proenkephalin and the ACTH/endorphin precursor (POMC) in AtT-20 cells is efficient cleavage of a Lys-Lys site in proenkephalin and not in POMC. The ability of AT/PE to process proenkephalin in a natural manner makes it a suitable model system to investigate elements involved in the processing of proenkephalin at Lys-Lys sites.