Isolation and quantitation of several new peptides from the canine neurotensin/neuromedin N precursor

Processing of chicken progastrin at post-Phe bonds by an aspartyl protease

Prohormones mature to biologically active peptide hormones through posttranslational modifications, which include endoproteolytic cleavages. Cleavages at mono- and dibasic sites are well characterized, and several of the responsible prohormone convertases have been identified. There is, however, evidence that endoproteolytic maturation occurs also at other sites. Among these, post-Phe cleavage occurs in the maturation of chicken progastrin, where the processing to gastrin-30 has been examined in detail. In this study we have characterized an endoprotease of the aspartic acid protease family in chicken and human tissue capable of cleaving at the Phe site. Enzymatic activity was monitored by radioimmunoassays using antibodies specific for the N- and C-termini exposed after cleavage. Analysis showed that only pepstatin, a specific inhibitor of aspartic proteases, inhibited the enzyme. The pH optimum of the enzyme ranged from pH 2 to pH 5. Amino acid substitution from Phe to Ala in the substrate completely abolished enzyme activity. The endoproteolytic activity was identified in chicken antrum and pectoral muscle as well as human cardiac and prostate extracts, suggesting that the enzyme has widespread biological functions. Experiments using recombinant cathepsin D and E indicated that neither is responsible for the endoproteolytic cleavage of chicken progastrin at post-Phe bonds.

BON cells display the intestinal pattern of neurotensin/neuromedin N precursor processing

Antisera towards the bioactive peptides, neurotensin (NT, 13 residues) and neuromedin N (NMN, 6 residues), as well as towards three regions of their 147-residue canine precursor were used to identify and to quantitate precursor-derived peptides in extracts of human BON cells. This cell-line, which was obtained from a human pancreatic carcinoid tumor, constitutively expresses NT/NMN mRNA and secretes NT. Quantitation of seven precursor-derived peptides led us to conclude that BON cells display the intestinal pattern of NT/NMN precursor processing, which is primarily characterized by the production of a large molecular (125 amino acid) form of NMN. Four large molecular components, identified by immunochemical analyses and Western blotting, displayed physico-chemical properties which, for the most part, were consistent with the structures predicted from the partially-known human mRNA sequence. However, as shown previously for these peptides in canine gut, the empirically determined M(r) and pI values were slightly higher than those predicted solely from the amino acid content, perhaps due to the presence of additional substituents. These results suggest that BON cells may provide a good in vitro model in which to study the regulation of intestinal NT/NMN precursor processing and the nature of the enzyme(s) involved.

Enhanced expression of neurotensin/neuromedin N mRNA and products of NT/NMN precursor processing in neonatal rats

Intestinal levels of immunoreactive neurotensin (iNT) and neuromedin N (iNMN), as well as mRNA for the NT/NMN precursor, were elevated during the suckling period in rats. While transient expression of NT/NMN was observed at 1-5 days of age in the proximal small intestine and colon, NT/NMN levels in the ileum increased to peak at 10-20 days of age and then decreased to adult levels. The levels of these peptides were not elevated in the central nervous system and pituitary over this time period. Chromatographic analyses of jejunoileal extracts indicated that large molecular forms of iNT and iNMN were present, constituting approximately 1.3% of total iNT and approximately 56% of total iNMN, respectively. Treatment of the large forms with pepsin, which is known to generate the fully immunoreactive peptides, NT(3-13), NT(4-13), and NMN, increased immunoreactivity tenfold (iNT) and 1.2-fold (iNMN). Thus, large forms actually constituted approximately 13% (iNT) and approximately 60% (iNMN). Based upon its physicochemical properties, large molecular iNMN was tentatively identified as a 125 residue peptide with NMN at its C-terminus [i.e., rat prepro-NT/NMN(23-147)]. The properties of large molecular iNT were most similar to those predicted for the entire precursor [i.e., rat prepro-NT/NMN(23-169)]. These results indicate a) that enhanced expression of NT/NMN occurs in a tissue-specific manner in rats during the suckling period; b) that the pattern of precursor processing in intestine yields primarily NT and a large molecular form of NMN.

A common precursor to neurotensin and LANT6 and its differential processing in chicken tissues

Antisera towards neurotensin (NT) and the structurally related peptide, LANT6, were used to characterize immunoreactive peptides and proteins in extracts of chicken tissues. A 17 kDa protein was identified by Western blotting as a potential precursor to NT and LANT6. However, the posttranslational processing of this common precursor appeared to be tissue specific, giving rise to disproportionate amounts of NT and LANT6, along with varying expression of a large molecular LANT6 (M(r), 15 kDa). The intestinal cells containing immunoreactive NT, LANT6, and large molecular LANT6 behaved similarly during fractionation by size and density. These activities also banded together in particles resembling vesicles during centrifugation of isotonic homogenates of tissue. These results suggest that chicken NT and LANT6 are biosynthesized as parts of the same precursor, the processing of which can give rise to a variety of products stored within secretory vesicles.

Induction of the neurotensin (NT) gene in PC12 cells gives rise to NT precursor (approximately 88%), NT(3-13)-like peptide (approximately 10%), and NT (approximately 2%)

Neurotensin (NT) is coexpressed with catecholamines in sympathetic neurons and adrenal chromaffin cells. A pheochromocytoma PC12 cell line can also be induced to express the NT gene and produce immunoreactive NT. In the present study, NT mRNA was quantified under various hormonal conditions and NT precursor synthesis rates were determined by pulse labeling and immunoprecipitation. In addition, NT precursor and NT-related products were measured using RIA and were characterized using HPLC and Sephadex chromatography. Neurotensin mRNA, NT precursor synthesis, and NT precursor/product levels were correlated. Surprisingly, NT appeared to be a minor product, both in cells and media: NT precursor (approximately 88%), NT(3-13)-like peptide (approximately 10%), and NT (approximately 2%). Neurotensin added to cultures was not converted to NT(3-13). Treatment of cells with 60 mM KCl or various secretagogues induced Ca(2+)-dependent release of NT precursor, NT(3-13), and NT in proportion to their cellular contents. These results suggest a) that NT precursor processing in induced PC12 cells was much slower than NT precursor synthesis, b) that NT(3-13) was a major product and NT a minor one, and c) that NT precursor and its products were stored within secretory vesicles.

PC12 cells can be induced to produce, but do not process, the neurotensin/neuromedin N precursor

Neurotensin and neuromedin N are two biologically active, related peptides that are encoded in the same precursor molecule. In the rat, the precursor consists of a 169-residue polypeptide containing in its C-terminal region one copy each of neurotensin and neuromedin N. Four Lys-Arg sequences, which are thought to represent putative processing sites, occur in the precursor molecule. Studies by others have shown that rat pheochromocytoma PC12 cells produced neurotensin and dramatically increased their neurotensin/neuromedin N precursor mRNA content in response to a combination of nerve growth factor, dexamethasone, forskolin, and Li+. Here, we investigated the effects of this combination of inducers on the posttranslational processing of the neurotensin/neuromedin N precursor in PC12 cells. Radioimmunoassays coupled to HPLC and arginine-directed tryptic cleavage of cell extracts were performed with five antisera specific for precursor sequences adjacent to basic doublets. Thus, mature neurotensin and neuromedin N represented less than 1% of the total precursor content in PC12 cells. The PC12 cell line may represent an interesting model with which one could transfect the recently cloned prohormone convertases PC1 and PC2, thereby allowing the study of the role of these enzymes in the processing of the neurotensin/neuromedin N precursor.