Antibodies Specific for α-N-Acetyl-β-Endorphins: Radioimmunoassays and Detection of Acetylated β-Endorphins in Pituitary Extracts

Abstract: Antibodies specific for α-N-acetyl-β-endorphins have been prepared by injecting into rabbits either α-N-acetyl-β-endorphin(1-31) or [α-N-acetyl, ε-acetyl-Lys⁹]-β-endorphin(1-9) linked by carbodiimide to bovine thyroglobulin. Both antisera were used to develop specific radioimmunoassays for α-N-acetyl-β-endorphins. The radioimmunoassays were used to measure α-N-acetylated β-endorphins in extracts of pituitary regions from different species. By comparison of the amounts of total β-endorphin and α-N-acetyl-β-endorphin immunoreactivity, a relative ratio of β-endorphin acetylation was obtained. The relative acetylation of β-endorphin was highest in rat posterior-intermediate lobe extracts (>90%). Beef and monkey intermediate lobes had a lower degree of acetylation (53 and 31%, respectively). Anterior lobe extracts from all three species contained low amounts of acetylated β-endorphin. Human pituitary extracts did not contain acetylated β-endorphins. By the use of cation exchange and high performance liquid chromatography, six different acetylated derivatives and fragments of β-endorphin were resolved in extracts of rat posterior-intermediate pituitaries. Two of these peptides corresponded to α-N-acetyl-β-endorphin(1-31) and -(1-27). One acetylated β-endorphin fragment had the same size as α-N-acetyl-β-endorphin(1-27) but was eluted earlier from the cation exchange column. This peptide had full cross-reactivity with antibodies directed against the middle and amino-terminal parts of β-endorphin. Compared with α-N-acetyl-β-endorphin(1-27), it had much less cross-reactivity with antibodies directed against the COOH-terminal part of β-endorphin, suggesting that it was a COOH-terminally modified derivative of β-endorphin(1-27). The remaining N-acetylated β-endorphin derivatives were eluted even earlier from the cation exchange column. The majority of these fragments were slightly larger in size than y-endorphin, i.e., β-endorphin(1-17), but smaller than β-endorphin(1-27). They had full cross-reactivity in an amino-terminally directed β-endorphin radioimmunoassay and a greatly diminished cross-reactivity with antibodies to the middle region of β-endorphin.     

Acetylated and nonacetylated forms of beta-endorphin in rat brain and pituitary

Extracts of rat posterior intermediate pituitary and extracts of brains from normal and hypophysectomized rats were separated by gel filtration chromatography and fractions were analyzed by both a classical β-endorphin radioimmunoassay and by a radioimmunoassay specific for α-N-acetyl β-endorphin. In posterior intermediate pituitary extracts, more than 90 percent of the β-endorphin-sized immunoreactive material was α-N-acetylated. In extracts of brains from normal rats, less than 2 percent of the β-endorphin-sized immunoreactive material corresponded to α-N-acetylβ-endorphin, whereas in brains from hypophysectomized animals, no α-N-acetylβ-endorphin-like material could be detected. Immunofluorescence on normal brain sections, using either affinity purified antibodies to α-N-acetylβ-endorphin or conventional β-endorphin antibodies, showed no α-N-acetylβ-endorphin immunoreactivity in β-endorphin neurons. Only in brain sections which had been acetylated $\text{in}\text{vitro}$ prior to immunostaining could α-N-acetylβ-endorphin-like material be detected in the β-endorphin neurons. These results suggest that—in contrast to the cells in the intermediate lobe of the pituitary—the β-endorphin in brain neurons is not α-N-acetylated and that the small amount of α-N-acetyl β-endorphin which can be found in extracts of brains from normal animals is probably of pituitary origin.     

Content of beta-LPH and its fragments (including endorphins) in anterior and intermediate lobes of the bovine pituitary gland

Radioimmunoassays (RIAs) specific for β-LPH_1–47, β-endorphin, α-MSH and β-MSH have been used to identify immunoreactive components in acid extracts from anterior and intermediate lobes of bovine pituitary gland after separation by chromatography on Sephadex G-50. When components in extracts of both lobes, eluting at the same position, were measured with the β-endorphin and β-LPH_1–47 RIA systems, marked quantitative differences were seen. The main components reacting with the β-LPH_1–47 system in anterior pituitary extract co-migrated with β-LPH and γ-LPH while in the intermediate lobe, the main immunoreactive component eluted at a position slightly later than β-endorphin. When the β-endorphin RIA system was used, relatively low amounts of immunoreactive material co-migrating with β-endorphin were seen in the anterior lobe extract while a highly predominant peak eluting at a position slightly later than β-endorphin was observed in intermediate lobe extract. Some β-MSH was seen in the intermediate lobe. These date indicate that the processing of β-LPH is markedly different in the anterior and intermediate bovine pituitary lobes: β-endorphin immunoreactive material predominates in the intermediate lobe whereas β-LPH and γ-LPH predominate in the anterior lobe.     

Presence of dynorphin-like immunoreactivity in rat pituitary gland and hypothalamus

Using a highly specific and sensitive radioimmunoassay for dynorphin(1-13), dynorphin-like immunoreactivity (dynorphin-LI) was detected in rat pituitary and hypothalamus. Gel chromatographic studies on Sephadex G-50 revealed three components of dynorphin-LI with molecular weights of approximately 7500-9500 (big dynorphin), 3500-5500 (intermediate dynorphin) and 1600-1900 (small dynorphin), the latter of which eluted at the same position as authentic dynorphin contamination in porcine ACTH extracts (Sigma). Dynorphin-LI in rat anterior pituitary existed mainly as big dynorphin, whereas dynorphin-LI in rat intermediate-posterior pituitary and hypothalamus eluted mainly at the position of authentic small dynorphin.     

Measurement of Total Opioid Peptides in Rat Brain and Pituitary by Radioimmunoassay Directed at the α-N-Acetyl Derivative

A sensitive assay, which cross-reacts with and is specific for diverse opioid peptides, is described. This is based on the prior acetylation of samples and subsequent radioimmunoassay with an antiserum highly specific for the acetylated NH₂ terminus of opioid peptides. The result is a procedure that can be used to investigate multiple forms of opioid peptides in extracts of biological material. The sensitivity of the assay is ?15 fmol of β-endorphin per incubation tube, i.e., ? 100-fold greater sensitivity than the radioreceptor assay used in our laboratory. The peptide concentration required for 50% displacement of trace ranged from 0.65 nM (β-endorphin) to 1.6 nM (Met-enkephalin). The assay apparently shows an absolute requirement for a free (or acetylated) NH₂ terminus corresponding to either a Leu- or Met-enkephalin sequence. Use of the assay with and without prior acetylation of sample provides a method for estimation of the ratio of acetylated:nonacetylated opioid peptides in crude or fractionated extracts. The procedure is used to investigate the forms of opioid peptide found in rat brain and pituitary.     

Localization of multiple forms of ACTH- and β-endorphin-related substances in the pituitary of the reptile, Anolis carolinensis

Immunohistochemical studies on the pituitary of Anolis carolinensis detected ACTH-like, β-endorphin-like, and 16K fragment-like immunoreactivity in distinct clusters of cells in the anterior lobe; ACTH-like, αMSH-like, β-endorphin-like, and 16K fragment-like immunoreactivity was detected in all the cells of the intermediate lobe. Crude acid extracts of both lobes, when alayzed by radioimmunoassay, gave displacement curves in ACTH and β-endorphin assays which were parallel to the appropriate synthetic standard. Only extracts of the intermediate lobe gave parallel displacement curves in an αMSH radioimmunoassay. Extracts of both lobes crossreacted with antiserum to 16K fragment, but the displacement curves were not parallel to that of mouse 16K fragment standard. The levels of immunoreactive ACTH and β-endorphin in the intermediate lobe were approximately 8-fold higher than in the anterior lobe. Fractionation of anterior lobe and intermediate lobe extracts by either gel filtration on Sephadex G-75 in 10% formic acid or sodium dodecyl sulfate polyacrylamide gel electrophoresis revealed multiple forms of ACTH-related and β-endorphin-related substances in both lobes. In the anterior lobe the major forms of immunoreactivity were, respectively, ACTH-sized and β-endorphin-sized. In the intermediate lobe the major forms of immunoreactivity were αMSH-sized, CLIP-sized, and β-endorphin-sized. In both lobes, antisera directed against ACTH and β-endorphin detected high molecular weight material with an apparent molecular weight slightly less than that of mouse pro-ACTH/endorphin; this material probably represents the putative common precursor for ACTH and β-endorphin in this species.     

Existence of a common precursor to ACTH and endorphin in the anterior and intermediate lobes of the rat pituaitary

Extracts of rat anterior and intermediate-posterior pituitary were fractionated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and assayed for immunoactive ACTH and endorphin. In both lobes the major forms of immunoactive ACTH have apparent molecular weights of 31,000 (31K), 20–21K, 14K, and 4.5K, and the major forms of immunoactive endorphin have apparent molecular weights of 31K (coincident with the peak of immunoactive ACTH), 13K (a βLPH-like peptide), and 3.5K (a β-endorphin-like peptide). However, the quantitative distribution of immunoactivity among the various forms differs greatly between the lobes. Assays using an extreme COOH-terminal ACTH antiserum indicate that the 31K ACTH/endorphin molecule in rat antierior and intermediate pituitary is similar to the pro-ACTH/endorphin molecule from mouse pituitary tumor cells. A radioimmunoassay that is specific for the NH₂-terminal non-ACTH, nonendorphin segment (referred to as 16K fragment) of the mouse pro-ACTH/endorphin molecule was used to assay extracts of rat pituitary. In addition to detecting material at 31K and 20–21K, the 16K fragment radioimmunoassay detects significant amounts of cross-reactive material with an apparent molecular weight of 16K in extracts of both lobes. This result also suggests that the structure and processing of the rat 31K ACTH/endorphin molecule is similar to that of mouse tumor cell pro-ACTH/endorphin. Cell suspensions were prepared from the anterior and intermediate lobes of the rat pituitary and maintained in culture for a 24-h period. The isolated cells from both lobes incorporate [³H] phenylalanine into immunoprecipitable ACTH- and endorphin-containing molecules. By sequential immunoprecipitation with ACTH and endorphin antisera, it is possible to demonstrate directly that a single molecule (31K ACTH/endorphin) has antigenic determinants for both ACTH and endorphin. Significant amounts of 31K ACTH/endorphin are released into the culture medium by isolated anterior lobe and intermediate lobe cells. The isolated intermediate lobe cells synthesize and secrete relatively large amounts of a β-endorphin-like molecule; the isolated anterior lobe cells secrete significant amounts of both a βLPH-like molecule and a β-endorphin like molecule. These same quantitative differences between anterior and intermediate lobe tissue were observed in immunoassays of extracts of the separated lobes and probably reflect differences in the processing of the common precursor. The isolated anterior lobe cells can be stimulated to release increased amounts of immunoprecipitable ACTH and endorphin by incubation with a cyclic AMP analog and a phosphodiesterase inhibitor.     

Gonadal steroids and anterior lobe dynorphin in the male rat

Immunoreactive (ir)-dynorphin levels were measured, and the species characterized by high performance liquid chromatography (HPLC), in the pituitary and hypothalamus of intact and castrate male rats. On HPLC, ir-dynorphin co-eluted with authentic dynorphin A 1-8, dynorphin A 1-17 and dynorphin 1-32 in the hypothalamus and intermediate lobe; in two different reversed phase (RP)-HPLC systems, anterior lobe ir-dynorphin co-eluted uniquely with dynorphin 32 (4K dynorphin). Anterior lobe levels of total ir-dynorphin were significantly lowered 7 days after castration, while HPLC profiles in all tissues remained unchanged. The change in anterior pituitary ir-dynorphin levels was reversed in a dose-related manner by dihydrotestosterone (15-500 micrograms/100 g b. wt/day); estradiol benzoate (3 micrograms/100 g/day) was without effect. The changes on castration and androgen administration suggest that gonadal steroids play a role in the regulation of dynorphin, as well as gonadotrophins and prolactin, within the anterior pituitary gland.     

Evidence for a common precursor for αMSH and β-endorphin in the intermediate lobe of the pituitary of the reptile Anolis carolinensis

Immunohistochemical studies on the pituitary of Anolis carolinensis detected ACTH-like, β-endorphin-like, and 16K fragment-like immunoreactivity in distinct clusters of cells in the anterior lobe; ACTH-like, αMSH-like, β-endorphin-like, and 16K fragment-like immunoreactivity was detected in all the cells of the intermediate lobe. Crude acid extracts of both lobes, when alayzed by radioimmunoassay, gave displacement curves in ACTH and β-endorphin assays which were parallel to the appropriate synthetic standard. Only extracts of the intermediate lobe gave parallel displacement curves in an αMSH radioimmunoassay. Extracts of both lobes crossreacted with antiserum to 16K fragment, but the displacement curves were not parallel to that of mouse 16K fragment standard. The levels of immunoreactive ACTH and β-endorphin in the intermediate lobe were approximately 8-fold higher than in the anterior lobe. Fractionation of anterior lobe and intermediate lobe extracts by either gel filtration on Sephadex G-75 in 10% formic acid or sodium dodecyl sulfate polyacrylamide gel electrophoresis revealed multiple forms of ACTH-related and β-endorphin-related substances in both lobes. In the anterior lobe the major forms of immunoreactivity were, respectively, ACTH-sized and β-endorphin-sized. In the intermediate lobe the major forms of immunoreactivity were αMSH-sized, CLIP-sized, and β-endorphin-sized. In both lobes, antisera directed against ACTH and β-endorphin detected high molecular weight material with an apparent molecular weight slightly less than that of mouse pro-ACTH/endorphin; this material probably represents the putative common precursor for ACTH and β-endorphin in this species.     

Modulation of in vitro release of beta-endorphin from the separate lobes of the rat pituitary.

The rate of in vitro release of β-endorphin immunoreactivity from the anterior lobe of rat pituitary increased in response to hypothalamic extract and lys-vasopressin. Lys-vasopressin, at a low concentration, initiated a pronounced (5–6 fold) dose-dependent, parallel increase in the release of β-endorphin and ACTH from the anterior lobe. Corticosterone (5·10^?7 M) did not influence basal but could suppress such stimulated release. These stimulants did not, however, change the rate of release from the intermediate/posterior lobe.Chromatography of incubation media showed that β-endorphin and β-lipotropin were released in parallel from the anterior lobe but only β-endorphin from intermediate/posterior lobe tissue.These findings suggest that the β-endorphin pools in anterior and intermediate lobes differ both in their mechanism of release and in the regulation of this process.     

Post-translational processing of pro-opiomelanocortin (POMC)-derived peptides during fetal monkey pituitary development. II. beta-Lipotropin (beta-LPH)-related peptides

We have studied the post-translational processing of POMC-derived peptides during fetal monkey pituitary development using immunoassay and reverse-phase high-performance liquid chromatography (RP HPLC). Whole pituitary glands obtained from Day 50 and 55 fetal monkeys and separated lobes From Day 65 to 155 were extracted, fractionated, and analyzed for beta-melanotropin (beta-MSH), midportion beta-endorphin (beta-EP), and acetylated beta-EP immunoactivity. Separated adult pituitary lobes were analyzed for comparison. At Day 50, POMC-containing cells were located in both the anterior and intermediate pituitary lobes by immunofluorescence staining, the majority of these cells were localized in the anterior lobe. The Day 50 and 55 whole pituitaries contained predominantly beta-lipotropin (beta-LPH), gamma-lipotropin (gamma-LPH), beta-EP(1-31), and 2.2-kda beta-MSH. No acetylated products were found in Day 50 whole pituitary extracts. By Day 55, carboxy-shortened and acetylated beta-EPs were barely detectable in whole pituitary extracts. These forms were more apparent in the Day 65 separated neurointermediate lobe (NIL) extracts, and were similar to adult proportions by Day 80. The adult anterior lobe contained predominantly beta-LPH, beta-EP, and gamma-LPH. Adult NILs contained almost exclusively 2.2-kda beta-MSH, alpha-N-acetyl beta-EP(1-31) and alpha-N-acetyl beta-EP(1-27). The production of 2.2-kda beta-LPH in the monkey NIL indicates that monkey beta-LPH is different from rat beta-LPH in that it must contain the paired-basic cleavage site required for the formation of 2.2-kda beta-MSH that is known to be lacking in rat beta-LPH. Another finding was that monkey beta-EP contains a Tyr residue at position 27 as found in human beta-EP but appears to have the rat Gln substitution at position 31. The post-translational processing patterns characteristic of each lobe were well established by midterm fetal development (Day 80).     

Isolation and characterization of α-N-acetylβ-endorphin(1–26) from the rat posterior/intermediate pituitary lobe

An extract from 50 rat posterior intermediate pituitaries was fractionated by gel filtration followed by cation exchange chromatography. α-N-Acetylated derivatives of β-endorphin-like molecules were detected with a specific radioimmunoassay for α-N-acetylβ-endorphins. Six peaks of α-N-acetylβ-endorphin-like immunoreactivity were observed in the cation exchange chromatography fractions. One of these peaks was purified to homogeneity using reverse phase high performance liquid chromatography (RP-HPLC). The isolated peptide was characterized by tryptic digestion followed by RP-HPLC and by amino acid analysis. The results showed that the isolated peptide was α-N-acetylβ-endorphin(1–26) with an oxidized methionine residue at position 5. Two previously unrecognized α-N-acetylβ-endorphin derivatives were also observed during the isolation procedure.     

Sex Differences in the Content of β-Endorphin and Enkephalin-Like Peptides in the Pituitary of Obese (ob/ob) Mice

Abstract: The β-endorphin content in pituitary extracts of male and female obese (ob/ob) and lean (+/?) mice was determined by radioimmunoassay. The amount of β-endorphin-like material contained in the pituitary of 3-month-old ob/ob male mice is similar to that of lean male mice. In contrast, the pituitary glands of female ob/ob mice have a greater amount of β-endorphin-like material than lean female mice. To determine with greater precision the molecular nature of the polypeptide that accounts for the increase in β-endorphin immunoreactivity, the various molecular forms of β-endorphin immunoreactivity were resolved by Biogel P-30 column chromatography. At least four peaks of immunoreactive material were detected. The first peak elutes in the void volume, and the second and the third peaks appear in the elution volumes of β-lipotropin and β-endorphin, respectively. That the material present in the void volume might be proopiocortin is supported by adrenocorticotropic hormone radioimmunoassay. The increased total β-endorphin immunoreactivity in pituitary glands of ob/ob mice is accounted for mainly by β-endorphin. The β-endorphin content of various brain structures of ob/ob mice is similar to that of lean littermates.     

Further characterization of the major forms of reptile beta-endorphin

Biosynthetically labeled reptile intermediate pituitary beta-endorphin-sized material was fractionated by SP-Sephadex ion exchange chromatography into two major opiate-active forms which eluted at 0.28 M NaCl and 0.32 M NaCl, respectively; the 0.32 M form of reptile β-endorphin (mw=3500), serves as the precursor for the 0.28 M form of reptile β-endorphin (mw=3200), (Dores and Surprenant, 1983). Analysis of tryptic digests of these reptile β-endorphins by paper electrophoresis at pH 3.5 and gel filtration on a Sephadex G-15 column indicated that there are two tyrosine residues, two arginine residues and one methionine residue in reptile β-endorphin. Furthermore, the NH₂-terminal tryptic peptide of both reptile β-endorphins is approximately nine amino acids in size and contains tyrosine, methionine and arginine. Analyses of chymotryptic/protease digests of the [³H]tyrosine-labeled NH₂-terminal tryptic peptide analyzed by descending paper chromatography revealed that the NH₂-terminal tyrosine of reptile β-endorphin is not -N-acetylated. A second tyrosine-containing tryptic peptide was detected in the COOH-terminal region of reptile β-endorphin; however this tryptic peptide differs in the two forms of reptile β-endorphin in terms of size and net charge at pH 3.5. These differences account for the apparent molecular weight differences and distinct ion exchange properties of the 0.28 M and 0.32 M forms of reptile β-endorphin. Thus in the reptile intermediate pituitary the principal post-translational mechanism for modifying β-endorphin is COOH-terminal proteolytic cleavage.     

Post-translational processing of pro-opiomelanocortin (POMC)-derived peptides during fetal monkey pituitary development. I. Adrenocorticotropin (ACTH) and alpha-melanotropins (alpha-MSHs)

We have studied the post-translational processing of POMC-derived peptides during fetal monkey development using immunoassay and reverse-phase high-performance liquid chromatography (RP HPLC). Pituitary tissues obtained from fetal monkeys ranging from Gestational Day 50 to 155 were fractionated and analyzed for ACTH- and alpha-MSH-related peptides and compared to adult forms. Extracts of whole pituitary from Fetal Days 50 and 55 contained ACTH(1-39) and very small amounts of CLIP (corticotropin-like intermediate-lobe peptide; ACTH(18-39))-like immunoactivity. Acetylated alpha-MSHs were not detectable at Day 50. alpha-MSHs were barely detectable at Day 55. By Day 65, when pituitary lobes were separable, small amounts of des-, mono-, and diacetyl alpha-MSH were detectable in NIL extracts, but not in anterior lobe extracts. ACTH(1-39) levels were negligible when compared to increasing alpha-MSHs through Fetal Day 80 to 155 in the intermediate lobe. The CLIP immunoactivity was negligible in Day 80 and adult anterior lobe extracts. Thus, lobe-specific proteolytic processing of ACTH-related peptides was well established by midterm gestation. Marked increases of alpha-N- and alpha-N,O-acetylated forms of alpha-MSHs were detected during middle and late stage fetal development. Diacetyl alpha-MSH was the predominant form of alpha-MSH in adult NIL extracts. No acetylated alpha-MSHs were found in anterior lobe tissues, thus adult anterior lobe extracts contained almost exclusively ACTH(1-39). However adult NIL extracts contained two distinct forms of CLIP-related immunoactivity. Therefore changes in post-translational processing patterns of ACTH-related and alpha-MSH-related peptides continued to some extent, postnatally. These data indicate that marked changes in post-translational processing of POMC-derived ACTH-related products occur during the first half of monkey gestation.     

Regional distribution of α-neo-endorphin in rat brain and pituitary

α-Neo-endorphin was isolated as the first form of “big” Leu-enkephalin and its complete amino acid sequence has recently been established. Using an antiserum raised against synthetic α-neo-endorphin, a highly sentitive and specific radioimmunoassay was developed. The antiserum practically possesses no cross-reactivity to Leu-enkephalin, dynorphin[1–13] and PH-8P, and very little to β-neo-endorphin. Distribution of α-neo-endorphin has been determined in rat brain and pituitary by the use of the highly specific antiserum. The highest concentration was observed at posterior lobe of pituitary. Furthermore, immunoreactive α-neo-endorphin was characterized by gel-filtration and high performance liquid chromatography, and shown to be identical with authentic α-neo-endorphin.     

alpha-Melanocyte-stimulating-hormone precursors in the pig pituitary.

The occurrence of intermediates from the processing of ACTH-(1-39) [adrenocorticotropic hormone-(1-39)] to alpha-melanocyte-stimulating hormone was investigated in normal pig pituitaries by the use of sensitive and specific radioimmunoassays for ACTH-(1-13), ACTH-(1-14), ACTH-(1-13)-NH2 and ACTH-(1-39). Fractionation by reverse-phase h.p.l.c. revealed ACTH(1-17) and their acetylated analogues. The intermediate lobe contained NO-diacetyl-ACTH-(1-13)-NH2, N-acetyl-ACTH-(1-13)-NH2 and ACTH-(1-13)-NH2. In addition, the corresponding ACTH-(1-14) peptides (the glycine-extended precursor of the amidated peptides) were detected in lower amounts in both the intermediate lobe and the anterior lobe. ACTH-(1-17), ACTH-(1-13) and their acetylated analogues could not be detected in the anterior lobe or the intermediate lobe. The results suggest that an endopeptidase initially cleaves ACTH-(1-39) at the Lys-16-Arg-17 bond. ACTH-(1-16) is then processed by a pituitary carboxypeptidase to ACTH-(1-14) and ACTH-(17-39) by the aminopeptidase to ACTH-(18-39).     

Evidence that Inhibition of Nicotine-Mediated Catecholamine Secretion from Adrenal Chromaffin Cells by Enkephalin, β-Endorphin, Dynorphin (1-13), and Opiates is not Mediated via Specific Opiate Receptors

Abstract: The opioid peptides Met- and Leu-enkephalin, dynorphin (1-13), and β-endorphin and the narcotic analgesics, morphine, levorphanol, and dextrorphan all produced a dose-dependent inhibition of nicotine (5 × 10^?6m )-mediated release of [³H]norepinephrine ([³H]NE) from bovine adrenal chromaffin cells in culture. None of these agents affected [³H]NE release induced by high K⁺ (56 mm ). Although the above results suggest that the opioid peptides and narcotic analgesics inhibit catecholamine release from adrenal chromaffin cells in culture, we suggest that these effects are not mediated by specific opiate binding sites, since (1) the inhibition was only produced with high concentrations of the agents—the threshold concentrations were 10^?7 to 10^?5m and higher; (2) the inhibition produced by the narcotic analgesics did not display stereospecificity, because the (d-isomer, dextrorphan, was slightly more active than the l-isomer, levorphanol; (3) the narcotic antagonists naloxone, naltrexone, and levallorphan did not reverse the inhibition produced by either the narcotic analgesics (e.g., morphine) or the opioid peptides (e.g., dynorphin). These three antagonists themselves inhibited the nicotine-mediated release of [³H]NE from the adrenal chromaffin cells in culture. Finally (4), the I₂-Tyr¹ substituted analogues of β-endorphin and dynorphin that are biologically less active than the parent compounds produced an inhibition of the nicotine-mediated [³H]NE release similar to that of their parent compounds. These results do not support the idea that high-affinity stereospecific opiate binding sites are involved in the inhibitory modulation of nicotinic evoked catecholamine release from bovine adrenal chromaffin cells in culture.     

Naltrexone reduces weight gain, alters “β-endorphin”, and reduces insulin output from pancreatic islets of genetically obese mice

Naltrexone, an opiate antagonist, was administered to young obese (ob/ob) and lean mice for five weeks. Animals had continuous access to food and received 10 mg/kg SC twice daily with equivalent volumes of saline given to controls. The effects on body weight, and pituitary and plasma levels of β-endorphin-like material were measured. Naltrexone-injected obese animals gained weight more slowly over the first three weeks while the weight gain of lean animals was not affected by naltrexone. Plasma levels of β-endorphin were shown to be significantly higher in untreated ob/ob mice and this difference increased with age (4–20 weeks). With naltrexone treatment, plasma levels in +/? mice rose and exceeded those in ob/ob. Saline treatment appeared to be a stress, and pituitary β-endorphins rose 4–6 fold in ob/ob compared with +/?. While naltrexone reduced the levels in ob/ob pituitary towards normal, no effect on β-endorphin levels in pituitary of lean mice was obtained. In vitro studies of effects of the opiate antagonists, naloxone, on insulin secretion by isolated islets provided additional evidence of resistance of lean mice to naloxone relative to ob/ob. (IRI secretion fell only in naloxone treated ob/ob islets.) These observations support the contention that this form of genetic obesity is characterized by elevated endogenous opiate levels and an increased sensitivity to opiate antagonists such as naltrexone or naloxone.     

Presence of immunoreactive alpha-endorphin in rat pituitary gland.

Utilizing radioimmunoassay for α-endorphin, we attempted to demonstrate immunoreactive α-endorphin in acid extracts of pars distalis and combined pars intermedia and pars nervosa of the rat pituitary gland after chromatography on Sephadex G-25. β-Lipotropin, β-endorphin and γ-endorphin were not converted into α-endorphin during the extraction and gel chromatographic procedures. Concentrations of immunoreactive α-endorphin determined after gel chromatography of extracts from pars distalis and combined pars intermedia and pars nervosa were 1.1±0.6 and 130±17 ng/mg wet tissue (mean±SE), respectively. Serial dilution of these extracts gave parallel lines to the standard curve of synthetic α-endorphin, but not to that of γ-endorphin or δ-endorphin. These results suggest the existence of immunoreactive α-endorphin indistinguishable in molecular size from synthetic α-endorphin in the rat pituitary gland.