Identification of cDNA encoding motilin related peptide/ghrelin precursor from dog fundus.

A novel protein expressed by entero-endocrine cells of the mouse stomach was named prepromotilin Related Peptide (ppMTLRP) since it shares sequence similarities with the prepromotilin (Tomasetto et al.). The mouse ppMTLRP was found identical to the rat precursor of ghrelin (ppghrelin), an endogenous ligand specific for the Growth Hormone Secretagogue receptor identified from rat stomach (Kojima et al.). In the present study the cDNA encoding the dog counterpart of ppMTLRP/Ghrelin has been isolated and sequenced. The dog ppMTLRP/Ghrelin cDNA showed scores of respectively 80% and 75% homology with its human and mouse counterparts. By translation of the dog ppMTLRP/Ghrelin cDNA sequences, two ORFs could be deduced encoding either a 117 amino acid ppMTLRP/Ghrelin or the deleted Gln14 ppMTLRP/Ghrelin, as it was also known in mouse, rat and man. The dog ppMTLRP/Ghrelin shared 91% similarity and 78% identity, and 89% similarity and 78% identity with the human and mouse ppMTLRP/Ghrelin proteins respectively. The best score of homology was found in the MTLRP/Ghrelin sequence itself. Indeed the dog MTLRP/Ghrelin peptide shared 100% similarity and 93% identity, and 96% identity and similarity, with the human and mouse MTLRP/Ghrelin. Using Northern blot analysis to study dog ppMTLRP/Ghrelin gene expression on dog adult gut tissues, maximal expression level was found in the stomach fundus and corpus, and no expression could be detected in the stomach antrum nor in the duodenum, jejunum, ileum, colon or liver. In conclusion, we have identified ppMTLRP/Ghrelin from dog, and found that it is highly conserved with man, mouse or rat. The expression pattern along the gastro-intestinal tract is similar to the expression pattern previously described in mouse.

Motilin in human milk: identification and stability during digestion.

The presence of motilin in human milk and the influence of human milk on the degradation of [125I][Nle13] porcine motilin by gastric and duodenal fluids were investigated. Milk and plasma samples were collected from 14 mothers, and motilin was measured by radioimmunoassay. Plasma levels were 416 +/- 37 pg/mL. In 8 defatted samples the motilin level was 105 +/- 14 pg/mL, in the six others levels were above 1000 pg/mL but dilution curves were non-linear. After solid-phase extraction milk levels were 108 +/- 21 pg/mL in 13 samples, in 1 sample the dilution curve was still non-linear. The stability of motilin after ingestion was studied in vitro by incubating [121I][Nle13] porcine motilin with gastric and intestinal juices obtained from newborns (10 times diluted). Incubations were performed at 37 degrees C at pH 1.8, 3.2 and 5.8 for the gastric fluid and at pH 7.4 for the duodenal fluid. After different times of intervals (5, 10, 20 and 30 minutes) intact motilin was precipitated with trichloroacetic acid and the radioactivity of the supernatant was determined. Motilin was rapidly degraded by gastric juice. The breakdown was greatest at pH 3.2 (74% after 30 minutes) and lowest at pH 5.8 (29%), the pH after milk feeding in neonates. Degradation by intestinal juice at pH 7.4 was also very rapid (77% after 30 minutes). Human milk and BSA inhibited partially the gastric digestion at pH 3.2 (17 and 29%, respectively). Digestion by intestinal juice was not affected by human milk and BSA. These results suggest that digestion of motilin in the stomach may be sufficiently retarded by human milk in the newborn to exert a biological role.

Isolation, sequence, and bioactivity of chicken motilin.

Motilin was isolated from acid extracts of the small intestine of chickens by a combination of gel filtration chromatography, ion-exchange, and reverse-phase HPLC. The purification was monitored using a radioreceptor assay. The sequence of chicken motilin is FVPFFTQSDIQKMQEK-ERNKGQ. Although the six residues differing from porcine motilin (4, 7-10, and 12) are mostly in the pharmacophore of porcine motilin, the affinity of chicken motilin and of the (1-14) fragment of chicken motilin for the motilin receptor of rabbit antral smooth muscle is not much reduced (pKds of 8.90 and 8.45), compared with the affinity of [Nle13]porcine motilin (pKd 9.12). With smooth muscle tissue of the chicken, however, receptors could not be demonstrated with binding studies. In the tissue bath chicken motilin induced a dose-dependent tonic contraction, which was most pronounced with muscle strips prepared from chicken jejunum. This response was blocked by the Ca2+ antagonist verapamil, but atropine, TTX, L-NNA, guanethidine, prazosin, and yohimbine had no effect. The pEC50 for chicken motilin in the chicken jejunum was 7.41. Motilins from other species had lower potencies, and [Phe3, Leu13]porcine motilin, an antagonist in the rabbit, was an agonist in the chicken. The motilin agonists erythromycin A and EM-523 were almost without effect. Tested against rabbit duodenum, chicken motilin had a smaller potency than mammalian motilins. Thus, chicken motilin and the chicken motilin receptor differ from their mammalian counterparts.

Purification and amino acid sequence of human motilin isolated from a motilin containing liver metastasis.

The acid extract of a liver metastasis from a patient with elevated plasma motilin levels contained large quantities of motilin (3.37 micrograms/ml). The extract was concentrated on a C18-column and motilin was isolated by gel chromatography (Sephadex G-50) followed by cation ion exchange chromatography (HR5/5 Mono-S) and three successive steps of reverse phase chromatography (Nucleosil 300-5 C18). The pure peptide was sequenced and the identity of porcine and human motilin was confirmed. This is the first report of a tumor containing large amounts of motilin.

Localization of motilin-immunopositive cells in the rat intestine by light microscopic immunocytochemistry.

Motilin-immunopositive cells (Mo cells) are known to exist in the upper small intestine of many species including man. However, the possible presence of Mo cells in the rat gastrointestine has remained obscure because antiserum against it raised in rabbit was found not to cross-react with motilin in the rat gastrointestine. The present study was designed to investigate the distribution of Mo cells in the rat gastrointestine by the peroxidase-conjugated second antibody method using newly raised chicken anti-motilin serum (CPV3). This antiserum was suggested to recognize the N-terminal region of the motilin molecule by enzyme-linked immunosorbent assays and immunocytochemical absorption test. Mo cells detected in the rat gastrointestine by immunocytochemistry were found to be distributed in the duodenum (1.5 cells/mm2), jejunum (2.2 cells/mm2), and ileum (0.028 cells/mm2), and no positive cells were found in the gastric body, gastric antrum, cecum, colon, or pancreas. The immunopositive cells in the rat intestine were spindle shaped or polygonal, scattered throughout the epithelium of the villi and crypts, and similar to those commonly observed in the upper small intestine of other species. These results indicate for the first time that motilin-immunopositive cells do exist in the rat intestine.

Purification and amino acid sequence of motilin from cat small intestine.

Motilin was isolated from cat small intestine by a series of chromatographic steps. Using a radioreceptor assay, based upon binding of iodinated porcine motilin to rabbit antral smooth muscle membranes, it was shown that cat duodenal mucosa contains about 495 ng/g tissue, the jejunal mucosa 161 ng/g tissue and the ileal mucosa 95 ng/g tissue motilin. The duodenal mucosa was extracted with 6% acetic acid and concentrated on a cation exchange Whatman CM-52 gel. After lyophilization the material was further purified by gel filtration (Sephadex G-50), followed by reverse phase (C18), cation exchange HPLC (Mono S) and three runs on a reverse phase HPLC (Nucleosil 300-5C18) column. The UV absorbance and the radioreceptor assay were used to monitor the purification. After Mono S chromatography two forms of motilin were detected. The major peak corresponded to a 22 amino acid peptide, which differed only from canine motilin at position 12, where Lys is replaced by Arg. The smaller peak probably corresponds to a deamidated form of this peptide. The sequence homology between cat and porcine/human motilin or cat and rabbit motilin is 81.8% and 72.7%, respectively. The conservation of the first six amino acids in all five species studied is striking, confirming that the biological activity of the peptide resides in the N-terminal part.

Separation of closely related large peptides by micellar electrokinetic chromatography with organic modifiers.

Large peptides with similar electrophoretic mobilities were separated by micellar electrokinetic chromatography (MEKC) with organic modifiers. [Leu13]motilin and [Met13]motilin differ by only one neutral amino acid residue. Because the electrophoretic mobilities of these peptides are almost identical, these peptides were not separated by capillary zone electrophoresis (CZE). Such large peptides have not been separated by conventional MEKC either, because they interacted strongly with the micelle. However, they were completely separated by MEKC when an organic solvent was added to the micellar solution. Some insulins, larger peptides than motilin, from different origins, which have very similar electrophoretic mobilities, were also successfully separated by the same technique. The size of peptides which were separated without organic modifiers was examined.

Rapid, small-scale preparation of gastrointestinal hormones by high-performance liquid chromatography on a C18 column.

A rapid reversed-phase high-performance liquid chromatography method was developed for the isolation of small quantities of biologically active gastrointestinal hormones, using a Varian MCH-10 C18 column. Biologically active secretin was isolated from contamination with other hormones, including cholecystokinin, gastrin, motilin, and vasoactive intestinal polypeptide, from samples of the acid perfusate of canine duodenum and from the crude acetic acid extract of canine antral mucosa containing less than 100 picomoles of secretin. The method also appeared to be suitable for the isolation of cholecystokinin octapeptide and motilin.

Rapid high-yield purification of canine intestinal motilin and its complete sequence determination.

Canine motilin has been purified from small amounts of canine intestine in a form suitable for microsequence analysis. The sequence determined is: Phe-Val-Pro-Ile-Phe-Thr-His-Ser-Glu-Leu-Gln-Lys-Ile-Arg-Glu-Lys-Glu-Arg- Asn-Lys - Ile-Arg-Asn-Lys-Gly-Gln. Canine motilin differs from porcine motilin at five positions. The rapid, high-yield (24% overall yield) microisolation techniques used for canine motilin should be suitable for the isolation of other basic peptides found in low levels in tissue that is available only in limited amounts. These methods should make the isolation and sequence determination of human brain and gut peptides more readily achievable.

Regulatory peptides of the gut and brain.

The concept of the gut-brain axis has emerged from the recent demonstration, mainly by radioimmunoassay and immunohistochemistry, that many peptides are common to both gut and brain cells. The general term regulatory peptide is at present the most appropriate for these peptides until more is known about their precise hormonal, neurotransmitter and neuromodulator activities. Consideration of possible local endocrine (paracrine) and neuroendocrine secretion necessitates re-evaluation of the importance of peripheral regulatory peptide concentrations. Central and peripheral administration of these peptides is a useful way to establish their potential regulatory roles in endocrine and nervous pathways. The concept of the gut-brain axis demonstrates the intimate relations between endocrinology and neuroendocrinology.

Purification and characterization of canine intestinal motilin.

A 22 amino acid peptide with motilin-like immunoreactivity was purified from acetic acid extracts of small intestinal mucosa from mongrel dogs. Sequential chromatography on carboxymethyl-cellulose, Sephadex G-50, CM cellulose, Biogel P6, and two steps of high-performance liquid chromatography were used for purification. Microsequence analysis of the purified product permitted unambiguous identification of residues 2-22 as -VPIFTHSELQKIREKERNKGQ. The sequence of porcine intestinal motilin is FVPIFTYGELQRMQEKERNKGQ. The amino terminal residue of the canine peptide could not be assigned with certainty since Phe, Lys, and Ser all were identified by analysis of PTH derivatives on the first sequencing cycle. Definite amino acid differences between canine and porcine motilin thus were identified in positions 7, 8, 12, 13 and 14. These differences did not alter immunoreactivity of canine motilin with antibodies specific for the carboxyl-terminal portion of porcine motilin, but probably explain markedly diminished immunoreactivity with antibodies to the amino or mid-portion of porcine motilin. Synthetic Phe1 canine motilin was prepared by a solid phase method. The synthetic peptide had the same pattern of immunoreactivity as natural canine motilin and was biologically active with a potency similar to synthetic porcine motilin for induction of premature activity fronts of the interdigestive motor complex in the small intestine of fasting dogs.

Solid-phase synthesis and biological activities of gastrointestinal hormones: secretin and motilin.

Many successful solid-phase syntheses of peptide chains in the region of 20-40 amino acid residues have now been routinely reported. Utilizing standard solid-phase synthetic methodologies but, particularly, new and powerful purification techniques we have been developing rapid and efficient preparative routes for the numerous neuro-gastrointestinal peptides. In the present study, secretin and motilin were obtained in 16% and 10% yields, respectively, after simplified two-step purification of hydrogen fluoride-cleaved peptides by gel filtration followed by preparation high performance liquid chromatography. Peptides were essentially homogeneous by TLC and analytical high performance liquid chromatography. Secretin was found to have full biological activity when tested against a standard sample of natural material for effects on pancreatic secretion in the dog. Motilin exhibited full biological activity on interdigestive motility in the dog. Secretin has been reported to undergo rearrangement with loss of bioactivity during purification and prolonged storage. We observed no obvious problems during our abbreviated purification schedule and have found no loss of purity of peptide which has been kept for 6 months as power lyophilized from dilute acetic acid.

[Radioimmunoassay of motilin (author's transl)]. / Die radioimmunologische Bestimmung von Motilin.

A specific radioimmunoassay for motilin is described and a few technical details concerning antibody production and tracer iodination are discussed. Though a variety of biological actions of motilin have been reported, its role in normal human physiology remains to be established. So far, the motilin radioimmunoassay brought no major break through to elucidate the physiology, disregard pathophysiology, of motilin.