L-Glutamic acid α-amide

Peptidylglycine alpha-amidating monooxygenase is a copper- and ascorbate-dependent enzyme that converts peptides with COOH-terminal glycine residues into the corresponding alpha-amidated product peptides. The relatively selective copper chelator N,N-diethyldithiocarbamate (DDC) and its disulfide dimer, disulfiram (Antabuse), were used to determine whether the availability of copper affects the production of two alpha-amidated pro-ACTH/endorphin-derived peptides, alpha-melanotropin (alpha MSH) and joining peptide. When mouse pituitary corticotropic tumor cells (AtT-20) were grown in medium containing micromolar concentrations of disulfiram or DDC, alpha-amidation of newly synthesized joining peptide was specifically inhibited in a dose-dependent manner. In rats injected twice with disulfiram or DDC, the ability of the intermediate pituitary to alpha-amidate newly synthesized alpha MSH and joining peptide was inhibited in a dose-dependent manner; at disulfiram doses equivalent to those used in alcohol abuse therapy (4 mg/kg/day), only about 10% of the newly synthesized peptides were correctly alpha-amidated. Chronic treatment of rats with DDC or disulfiram produced a dose-dependent increase in the pituitary content of glycine-extended alpha MSH and joining peptide; the total amount of pro-ACTH/endorphin-related material was unaltered. After 11 days of treatment with 4 mg/kg/day disulfiram, about one-third of the pituitary alpha MSH and joining peptide were present in the glycine-extended rather than the alpha-amidated form; pituitary extracts normally contain almost entirely alpha-amidated peptides.

Human pituitary tumours, obtained at surgery for Cushing's disease and Nelson's syndrome, were extracted and the content and molecular forms of pro-opiomelanocortin (POMC)-derived peptides determined by radioimmunoassay, gel chromatography, reversed-phase high-performance liquid chromatography (HPLC) and sequence analysis. In the tumours from patients with Cushing's disease the mean concentrations of amidated peptides relative to the total amount of POMC were as follows: alpha-MSH, 1.7%; amidated gamma-MSH (gamma 1-MSH), 8.5% and the peptide linking gamma-MSH and ACTH in the precursor (hinge peptide or joining peptide) in its amidated form (HP-N), 17.1%. The same relative concentrations in the tumours from patients with Nelson's syndrome were 8.5% (alpha-MSH), 7.5% (gamma 1-MSH) and 12.2% (HP-N). More than 95% of the ACTH(1-39) immunoreactivity eluted as synthetic ACTH(1-39) by gel chromatography and HPLC. The remaining ACTH(1-39) immunoreactivity eluted as partly glycosylated high molecular weight forms. All the alpha-MSH and its glycine-extended precursor ACTH(1-14) were of low molecular weight, mainly non- or mono-acetylated forms, but significant amounts of diacetylated analogues were also present. gamma 1-MSH and gamma 2-MSH immunoreactivities eluted as high molecular weight forms and were partly glycosylated. No low molecular weight forms of gamma 1-MSH or gamma 2-MSH could be detected in the pituitary tumours. Amidated hinge peptide was mainly of the 30 amino acid form. In conclusion, all the molecular forms of the amidated peptides detected in tumours from patients with Cushing's disease and Nelson's syndrome were similar to the molecular forms found in the normal human pituitary. The main difference between the tumours and the normal pituitary was the greater amount of peptides produced, particularly alpha-MSH and gamma 1-MSH.

The proteolytic processing pattern of pro-ACTH/endorphin in rat hypothalamus is similar to the pattern in the pars intermedia; peptides the size of beta-endorphin, gamma-lipotropin (gamma-LPH), corticotropin-like intermediate lobe peptide (CLIP), alpha-melanotropin (gamma-MSH), joining peptide, and glycosylated gamma 3-MSH all represent predominant end products. Equimolar amounts of beta-endorphin-, alpha-MSH-, CLIP-, gamma-LPH-, and joining peptide-related immunoreactivity are found in hypothalamic extracts (approximately 3 pmol per hypothalamus). Although the proteolytic processing pattern in the hypothalamus is similar to that in the pars intermedia, a tissue-specific posttranslational processing pattern was detected. Ion-exchange analysis of beta-endorphin-sized immunoreactive material from hypothalamic extracts resolves three major forms, corresponding to beta-endorphin(1-31), beta-endorphin(1-27), and beta-endorphin(1-26). The alpha-N-acetylated forms of endorphin represent less than 10% of the total beta-endorphin immunoreactivity. Analyses of hypothalamic alpha-MSH-sized molecules with acetyl- and amide-directed alpha-MSH antisera suggest that hypothalamic alpha-MSH is fully amidated, but largely not alpha-N-acetylated. Fractionation by reverse-phase high-performance liquid chromatography (HPLC) confirms that greater than 85% of the alpha-MSH immunoreactivity corresponds to ACTH(1-13)NH2 or its sulfoxide, and less than 10% corresponds to alpha-MSH [alpha-N-acetyl-ACTH(1-13)NH2] or its sulfoxide. Isoelectric focusing demonstrates that 83-93% of hypothalamic CLIP is phosphorylated. Isoelectric focusing suggests that the majority of the hypothalamic gamma-LPH-sized immunoreactive material is indistinguishable from gamma-LPH synthesized by pituitary melanotropes. The minor extent of alpha-N-acetylation of alpha-MSH and beta-endorphin, the limited carboxyl-terminal proteolysis of beta-endorphin, and the extensive phosphorylation of CLIP represent major differences between the posttranslational processing patterns of pro-ACTH/endorphin in the hypothalamus and pars intermedia.