Precursor forms of neurotensin (NT) in cat: processing with pepsin yields NT-(3-13) and NT-(4-13)

Basic proteins present in 0.1 N HCl extracts of feline CNS and intestine were found to liberate immunoreactive neurotensin (iNT) when treated with hog pepsin. These protein substrates were separated using Sephadex G-25, Sephadex G-75 and reverse-phase HPLC. In a calibrated SDS-polyacrylamide gel electrophoresis system, the major substrate from cat ileum exhibited a molecular weight of ca 16 kDa and minor substrates were observed at 30, 40 and 65 kDa. As shown previously for synthetic NT, pepsin-treatment of feline ileal NT converted it into the fully immunoreactive NT-(4-13) fragment (yield, 95%). When treated with pepsin, the partially purified ileal substrates gave rise to 4 immunoreactive peptides, one of which (ca 15% of total) eluted with the same retention time as NT-(4-13) while the major peptide formed (ca 40% of total) eluted near to the position of NT-(3-13). Both these products reacted equally well with two different antisera towards the C-terminal 5- and 8-residues of NT and were not recognized by an N-terminal antiserum. Experiments using various proteases demonstrated that the NT-related sequence(s) were located internally in each substrate and suggested that they were bounded by double basic residues. Substrate activity in isotonic homogenates of feline spinal cord, brain, adrenal and ileum cosedimented with iNT during equilibrium centrifugation, apparently in association with vesicle and/or synaptosomal particles. These findings indicate that basic proteins, colocalized with NT in vesicle-like particles of CNS, adrenals and ileum, could serve as precursors to this peptide, being liberated by pepsin-related enzyme(s).     

Immunochemical characterization of neurotensin-like peptides in chicken

Using radioimmunoassay and 3 region specific antisera toward bovine neurotensin (NT), the NT-like peptides in chicken have been shown to differ from NT but to strongly resemble its COOH-terminal region. Three substances were identified, one of which resembled NT biologically and appeared to share 7 or 8 of its COOH-terminal residues. The two other peptides were smaller than NT but seemed to possess 4–6 residue homologies with it. Tissue distribution studies indicated that the chicken pancreas and thymus had unusually high levels of this material (>200 fold that in rat) and that the 3 substances were distributed differently in tissues. Chromatographic studies showed that the peptides obtained from brain, intestine, thymus, and pancreas were similar. These results, demonstrating evolutionary conservation of the COOH-terminal region of NT, are in keeping with the known importance of this region for biological activity. These findings also suggest the existence of an NT-family of peptides serving multiple biological roles.     

Rapid proteolytic generation of neurotensin-related peptide(s) and biologic activity during extraction of rat and chicken gastric tissues

Using a radioimmunoassay directed toward the COOH-terminal, biologically active region of mammalian neurotensin (NT), the rapid (within seconds) generation of immunoreactive NT (iNT) during acid extraction of mammalian and avian gastric tissues has been demonstrated. Levels of iNT were shown to increase 25-200-fold in time. The reaction occurred in 0.1 N HCl and 2 N acetic acid and was prevented by raising the pH above 5 or by adding acetone. The temperature and pH dependence and the ability of pepstatin A to inhibit the reaction suggested the involvement of a pepsin-related acid protease. Furthermore, the reaction could be mimicked by incubating a stabilized gastric extract with hog pepsin at pH 2. Size exclusion chromatography demonstrated the presence of a precursor-like substance with an apparent Mr of 60,000. Although iNT generated in avian and mammalian gastric extracts could be distinguished chromatographically from NT in that species, the partially purified gastric iNT was active in a bioassay for NT which quantitates changes in vascular permeability after intradermal injection into rats. One might suggest that iNT serves as a signal within the gastric lumen, being generated at low pH by secreted pepsin. It is also possible that iNT could be formed within blood or gastric interstitial fluid by the action of pepsin-related (cathepsin or renin-like) enzymes at normal physiologic pH.     

Rapid degradation of neurotensin by stimulated rat mast cells

A RIA towards neurotensin (NT) using C-terminal- and N-terminal-specific antisera was used to study degradation of this tridecapeptide by isolated rat mast cells. Incubation of NT (10 μM) with peritoneal or pleural mast cells resulted in a rapid loss of NT immunoreactivity (iNT), as measured by C-terminal-directed antiserum, with little effect on N-terminal iNT. The rate of the reaction was faster with pleural cells (T_1/2, 30 s) than with peritoneal cells (T_1/2, 180 s) and was > 10-fold slower in the presence of metabolic poisons. The enzyme(s) involved is most likely released from the cells during secretion, as NT was degraded by media conditioned by compound 48/80-stimulated mast cells 40–60 times faster than by media from unstimulated cells. This degradation by conditioned media was concentration dependent, pH dependent, and temperature sensitive. HPLC analyses indicated a near stoichiometric conversion of NT to NT(1–12) (66%) and NT(1–11) (34%) after incubation for 10–30 s with conditioned media. By 30 min only NT(1–11) and NT(1–10) were present. Phenanthroline (1 mM), an inhibitor of carboxypeptidase, prevented the loss of C-terminal iNT and the generation of NT(1–12) and NT(1–11). While NT(1–12) was effective in releasing histamine from mast cells in vitro and increasing vascular permeability in vivo, NT(1–11) was not. These results suggest that carboxypeptidase-like enzyme(s) could modulate the level and form of NT-related peptides in various states involving activation of mast cells.     

Radioimmunoassay for Lys8, Asn9, neurotensin 8–13: Tissue and subcellular distribution of immunoreactivity in chickens

A sensitive and specific radioimmunoassay (RIA) for Lys⁸, Asn⁹, neurotensin 8–13 (LANT-6) has been developed which utilizes ¹²⁵I-labeled LANT-6 and rabbit antisera raised towards conjugates of synthetic LANT-6 and bovine thyroglobulin. The antiserum described (TG-22) allows the detection of ca 100 fmol of LANT-6 and crossreacts <0.01% with chicken or bovine NT. Dose-response relationships for the native (chicken) and synthetic peptides were indistinguishable. Using this assay the distribution of immunoreactive LANT-6 (iLANT-6) through various tissues of the chicken was studied and compared with that of chicken NT (iNT) determined by RIA. Both iNT and iLANT-6 were found primarily in the brain and gastrointestinal tract, however, their regional distributions were found to differ. Subcellular distribution studies in homogenates of chicken brain indicated that obth iNT and iLANT-6 were associated with synaptosome-like and vesicle-like particles. In homogenates of small intestine, pancreas and colon iNT and iLANT-6 appeared to be within osmotically sensitive, sedimentable particles. Analyses using high pressure liquid chromatography established that chicken iLANT-6 co-eluted with the synthetic peptide and that similar substances were present in extracts of rat brain and intestine. These results are consistent with “messenger” roles for these peptides.     

A glucagon-like peptide, structurally related to mammalian oxyntomodulin, from the pancreas of a holocephalan fish, Hydrolagus colliei.

The pancreatic islets of the holocephalan fishes contain, in addition to A-, B- and D-cells, X-cells, which are immunoreactive towards antisera directed against the N-terminal region of glucagon but not towards antisera directed against the C-terminal region. A 36-amino-acid-residue peptide was isolated from the pancreas of a holocephalan fish, the Pacific ratfish (Hydrolagus colliei), that shows homology (69%) to mammalian glucagon in its N-terminal region and is reactive towards an N-terminally directed antiserum. Reactivity towards C-terminally directed antisera is prevented by the presence of a 7-residue C-terminal extension to the glucagon sequence that shows limited homology to the C-terminal region of glucagon-37 (oxyntomodulin). It is proposed that this peptide represents a major storage product of the islet X-cell.     

Immunoreactive atrial natriuretic peptide in the guinea pig spleen

The presence of immunoreactive ANP precursor-like material in the guinea pig spleen is suggested. This is based on the following experimental evidence: An acidic extract of guinea pig spleen analysed by Sephadex G-50 gelfiltration contained 4.6 pmol/g wet tissue immunoreactive atrial natriuretic peptide (IR-ANP), coeluting with the 15 kDa synthetic ANP (2-126). Gelfiltrated IR-ANP material was further submitted to reverse phase high performance liquid chromatography and monitored by radioimmunoassay employing two antisera. One antiserum recognizes the C-terminal of ANP (1-126), the second is directed against the N-terminal sequence. Both antisera revealed material eluting with synthetic ANP (2-126). Furthermore, immunohistochemical analysis suggests this ANP-like material to be localized mainly at the periphery of the white pulp of the spleen. These findings link ANP with the immune system.     

Actin antibodies. Preparation and characterization of antibodies specific for smooth-muscle actin isoforms.

We have determined the specificity of sera elicited by glutaraldehyde-stabilized bovine aortic actin. This modification induces a high titre of antibodies directed against the N-terminal (residues 1-39) and the C-terminal region of smooth-muscle actins. The crude antisera were purified on peptide (corresponding to the 1-9 or 1-8 N-terminal sequences of smooth-muscle isoactins)-polyacrylic-resin columns. By fractionating the antisera we obtained oligoclonal antibody populations specific for each isoactin.     

Isolation and primary structure of an amphibian neurotensin.

Using a radioimmunoassay system employing an antiserum which recognises the common C-terminal tripeptide (YIL) of neurotensin (NT) and neuromedin N (NN), immunoreactivity was identified in extracts of brain (65.8 pmol/g), small intestine (44.2 pmol/g) and rectum (13.2 pmol/g) of the European common frog (Rana temporaria). No immunoreactivity was detected in extracts of stomach and skin. Reverse-phase HPLC analysis of each tissue extract resolved a single immunoreactive peptide with identical retention time in each case. The immunoreactive peptide was isolated by reverse-phase HPLC from brain extracts and an N-terminal pyroglutamyl residue was successfully removed enzymatically. The molecular mass of des(pyroglutamyl) frog NT, determined by plasma desorption mass spectroscopy, was 1440 Da. The primary structure of this peptide was determined by gas-phase sequencing and the calculated molecular mass, 1440.7 Da, was in close agreement with that derived by mass spectroscopy. The full primary structure of frog NT was established as: QSHISKARRPYIL. When compared with bovine NT, frog NT exhibits five amino acid substitutions in the N-terminal region, whereas the C-terminal hexapeptide sequence (RRPYIL), which mediates the classical biological effects of NT, is completely conserved. Amphibia thus possess a tridecapeptide NT which is analogous to that of higher vertebrates and considerable constraints on the primary structure of the C-terminal biologically-active core have existed for a vast evolutionary time span.     

Comparative studies on the nonprotein but nondialysable sugar-peptide fraction isolated from the plasma of various classes of vertebrates.

1. The nonprotein but nondialysable ninhydrin-positive substances isolated from plasma of some species belonging to four classes of vertebrates (fishes, amphibians, birds and mammals) were studied. 2. In all species studied (Cyprinus carpio, Salmo gairdneri, Rana esculenta, Rana temporaria, Gallus domestica and Rattus rattus) a similar group of nondialysable ninhydrin-positive substances may be isolated from the plasma by Sephadex G-25 filtration followed by dialysis. 3. Thin-layer Sephadex G-25 electrophoresis disclosed in birds (Gallus domestica) the lack of one ninhydrin-positive band contrary to the species of other classes of vertebrates. 4. Electrochromatography showed in all species studied an alteration in the composition of the basic peptide fractions and in birds the lack of one neutral peptide.     

The stability and metabolism of intravenously administered neurotensin in the rat

The clearance and metabolism of synthetic and tritiated (³H) neurotensin (NT) were studied following its intravenous injection in a pharmacologic dose (500 pmol/kg) into anesthesized rats. Immunoreactive NT (iNT), measured in a radioimmunoassay (RIA) with use of a carboxyl-(C)-terminal directed antiserum, displayed an apparent half-life ($\text{t}\text{1}\text{2}$) of 0.55 min, while that measured by an amino-(N)-terminal directed antiserum had a $\text{t}\text{1}\text{2}$ of 5 min. The radiolabel from injected ³H-NT (³H on Tyr^3,11) had a $\text{t}\text{1}\text{2}$ of 6.5 min. High-pressure liquid chromatography of extracts of plasma obtained from the circulation 0.5–3 min after injection of NT and ³H-NT showed the presence of NT and the generation mainly of the fragments NT^1–8, NT^1–11, and NT^9–13, as well as free ³H-labeled tyrosine. The apparent half-lives of intravenously injected synthetic NT^1–8, NT^1–11 and NT^1–12 measured with the N-terminal RIA were 9, 5 and 5 min, respectively, while that for NT^9–13 was less than 0.5 min. These results indicate that exogenously injected NT is rapidly metabolized to form N-terminal fragments which are cleared more slowly than NT. These findings suggest that use of N-terminal antisera to detect the release of endogenous NT into the circulation is likely to yield measurements of the fragments NT^1–8 and NT^1–11 which thus far have been found to be biologically inactive.     

Localization and characterization of the N-terminal fragment of atrial natriuretic factor (ANF) precursor in the frog heart

The localization of the N-terminal fragment of the atrial natriuretic factor (ANF) precursor in the heart of the frog Rana ridibunda was examined by the indirect immunofluorescence and the immunogold techniques using an antiserum directed against synthetic rat ANF (Asp11-Ala37). At the optic level, positive material was found in most atrial myocytes. Staining of consecutive sections of frog heart with antibodies against N-terminal and C-terminal regions of the proANF molecule showed that both peptides are contained in the same cardiocytes. In the rat atrium, antibodies against the N-terminal ANF region induced a more intense labeling than in the frog atrium. Electron microscopic studies indicated that all secretory granules present in frog atrial cardiocytes contain N-terminal ANF-like immunoreactive material. The positive material localized in frog atrium was characterized by gel filtration and radioimmunological detection. Serial dilutions of frog atrial extracts exhibited displacement curves which were parallel to that obtained with synthetic human ANF (Asn1-Asp30). Sephadex G-50 gel chromatography of the immunoreactive material showed that the N-terminal ANF-like immunoreactivity eluted in a single peak corresponding to high molecular weight material. These results indicate that the N-terminal fragment of frog proANF is immunologically and biochemically related to the homologous mammalian peptide.     

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 1.3% of total iNT and 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 13% (iNT) and 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.     

Evidence for the presence of ANP-precursor material in the rat thymus

Acidic extraction of the thymus from two day old rats followed by purification on Sephadex G-50 gelfiltration revealed the presence of atrial natriuretic peptide-like material (IR-ANP) by radioimmunoassay. Verification of the obtained immunoreactivity has been achieved by the use of two different types of antisera, i.e. two antisera directed against ANP (99-126), the other antiserum recognizing the N-terminal fragment (11-37) of the precursor ANP (1-126) molecule. In addition, reverse phase high performance liquid chromatography (RP-HPLC) and high performance gel permeation chromatography (HP-GPC) monitored by the three antisera have been employed for analysis of the extracted IR-ANP. In both systems the IR-ANP corresponded to the 15 kDa-ANP molecule (1-126). Furthermore, by using immunohistochemical techniques a distinct localization of the IR-ANP material could be demonstrated. The outer cortical area of the thymus, containing mostly lymphoid cells, showed extensive immunostaining with the three different antisera. The data reported here indicate that the rat thymus is a source of ANP.     

A fatty acid-binding protein and a protein disulphide isomerase-related protein expressed in urochordate gonad cytosol

Despite the evolutionary-tree data suggesting that gene duplication leading to the divergence of the three branches which heart, liver and intestinal fatty acid-binding proteins belong to must have occurred before the vertebrate/invertebrate split, only the heart fatty acid-binding protein has been reported for invertebrates. In an attempt to shed light on this apparent inconsistency the presence of the other two branch members was investigated in the Urochordata Molgula pedunculata, an ascidian species close to vertebrates. The mantle-, gonad- and digestive tube-cytosolic fractions, obtained by centrifugation at 106,000 g, were incubated separately with [1-(14)C]palmitic acid and then fractionated on a Sephadex G-75 column. In the case of gonads and digestive tube, radioactive peaks corresponding to a molecular mass of 14-16 kDa, characteristic of fatty acid-binding proteins, were detected. When the experiment was performed on the mantle, this peak showing fatty acid binding capacity was absent. Western Blot of the radioactive 14-16 kDa Sephadex fraction from the urochordate gonad cross-reacted with rat liver fatty acid-binding protein anti-serum but did not do so with anti-rat intestinal, adipocyte or heart fatty acid-binding protein antisera. The material from the digestive tube was not recognized by any of the antisera. The most abundant protein in said 14-16 kDa fraction was a protein disulphide isomerase-related protein. Its partial amino acid sequence was determined.     

Rat testis immunoreactive LH-RH differs structurally from hypothalamic LH-RH

Luteinizing hormone releasing hormone immunoreactivity (LH-RH-IR) has been identified in acetic acid extracts of adult rat testes and partially purified by immunoaffinity chromatography. On Sephadex G-100 this material separated into four major peaks of >100K, ～32K, ～5K and ≤4K daltons. The ≤4K peak of LH-RH-IR eluted later than synthetic hypothalamic LH-RH decapeptide on Sephadex G-25. Antibody binding studies on the various LH-RH-IR species with antisera specific for different regions of synthetic LH-RH decapeptide indicate that all the testicular LH-RH-IR molecules have C-terminal immunological homology with the hypothalmic decapeptide but differ towards the N-terminus of the decapeptide sequence.     

Radioimmunoassay of neuropeptide Y

The development of a radioimmunoassay to the newly isolated peptide, neuropeptide Y is described. Four separate antisera have been developed using different immunisation schedules. Two of these antisera (YNI and YNIO) are directed to the C-terminal region of the peptide and cross-react with the related peptide PYY, whereas YN7 is specific being directed to the N-terminal region of NPY, YN6 is similarly specific for NPY, but is unable to bind the available fragments. These four antisera provide similar results for determination of NPY immunoreactivity within porcine brain extracts, however YN6 consistently undervalues all extracts from the other species examined (human, rat, guinea pig, cat and mouse). Chromatographic analysis by means of reverse phase high pressure liquid chromatography (HPLC) shows that NPY immunoreactivity of human extracts elutes in an earlier position than the porcine standard. It seems likely therefore that human and porcine NPY differ in their amino acid sequences.     

Highly acidic proteins from human brain: purification and properties of Glu-50 protein

Three extremely acidic proteins were isolated from human brain and purified to apparent homogeneity. One of them, Glu-50 protein, contained much glutamic acid (about 50% of the total amino acids). Its purification involved ammonium sulfate fractionation, DEAE-Sephadex A-50 chromatography, and gel filtration on Sephadex G-100 and G-75. Its molecular weight was determined to be 11,000 by SDS polyacrylamide gel electrophoresis and 34,000-36,000 by gel filtration on Sephadex G-75, suggesting that it consists of three identical polypeptide chains. Its isoelectric point was pH 3.9. Its N-terminal amino acid sequence was NH2-Asp-Glu-Pro-Pro-Asp-Glu and its C-terminal amino acid was Lys. It contained no detectable carbohydrate.     

Pepsin-mediated processing of synthetic precursor-like sequence yields neurotensin-like peptide.

A 15 amino acid synthetic peptide, which spanned the dibasic cleavage site C-terminal to neurotensin (NT), in its 170-residue canine precursor, was synthesized by solid-phase methods. Using this substrate in combination with a radioimmunoassay specific for the C-terminal region of NT, a simple assay was developed to monitor protease-mediated cleavage of the Leu8-Lys9 bond in the substrate. Hog pepsin and the related enzymes, rhizopus pepsin, bovine cathepsin D, and mouse renin, were found to be effective in this assay, pepsin cleaving only this bond to liberate the NT-like sequence. The pH dependence of the reaction indicated that pepsin, cathepsin D, and renin exhibited significant activity at pH's characteristic for secretory vesicles (pH 5.5-6.5). In addition, pepsin and cathepsin D were shown to process the native precursor at pH's as high as 5.5. These results, although not proof, are consistent with the idea that endoproteases with pepsin-like specificity may be involved in the processing of the NT precursor in neural/endocrine cells.     

Isolation and purification of a neurodepressing hormone from the eyestalk of Procambarus bouvieri (Ortmann).

1. A neurodepressing hormone has been isolated and purified to homogeneity from aqueous extracts of 2000 eyestalks of the Mexican crayfish Procambarus bouvieri (Ortmann). 2. Purification was achieved by gel filtration on Sephadex G-25 and G-15, and preparative paper electrophoresis at four pH valueimately 1200 molecular weight and composed of neutral amino acids. 5. No N-terminal group could be found. From its electrophoretic behavior it is concluded that the C-terminal group is also blocked.