Characterization and Regional Distribution of Peptides Derived from the Vasoactive Intestinal Peptide Precursor in the Normal Human Brain

To study the biosynthetic processing of the precursor for vasoactive intestinal peptide (prepro-VIP) in the human brain, we have developed antisera against the five functional domains of the precursor molecule: prepro-VIP 22-79, peptide histidine methionine (PHM), prepro-VIP 111-122, VIP, and prepro-VIP 156-170. The antisera were used in radioimmunoassays in combination with HPLC to identify and quantify the peptides in regions of the human brain. All five peptides were expressed, but mainly in nonequimolar ratios. In only three regions were the same amounts of VIP and PHM found; in the remaining areas the concentration of PHM was two-thirds that of VIP. The concentrations of prepro-VIP 22-79, prepro-VIP 111-122, and prepro-VIP 156-170 were considerably lower than the corresponding VIP concentrations, and the relative concentration of prepro-VIP 111-122 differed between cortical and subcortical areas. A small proportion of the VIP precursor followed a pathway in which the dibasic conversion site after PHM is not cleaved, as evidenced by the presence of a C-terminally extended form of PHM. Finally, it was found that the C-terminal lysine residue of prepro-VIP is not removed during processing. The findings indicate that differences in the posttranslational processing of prepro-VIP exist in subpopulations of neurons in the human brain.     

Biosynthetic Processing of Preprovasoactive Intestinal Polypeptide in Parasympathetic Neurons of the Sphenopalatine Ganglion

Abstract: The precursor for rat vasoactive intestinal polypeptide (preproVIP) is processed by proteolytic cleavage into a signal peptide and five further functional domains: preproVIP 22–79, peptide histidine isoleucine (PHI), preproVIP 111–122, VIP, and preproVIP 156–170. To investigate the biosynthetic processing of preproVIP in peripheral parasympathetic neurons, the sphenopalatine ganglion and one of its projection areas, the nasal mucosa, were used. By immunohistochemistry it was shown that in the sphenopalatine ganglion, preproVIP-derived peptides are localized mainly in neuronal cell bodies, whereas in the nasal mucosa immunoreactivity was found only in nerve fibers and terminals. The peptides were quantified and characterized by radioimmunoassay, HPLC, and gel chromatography using antisera specific for the different precursor products. In the rat sphenopalatine ganglion, the different peptides were found in approximately equimolar amounts, with the exception of PHI and its C-terminally extended variant, PHV, which were present at considerably lower concentrations. However, in the nasal mucosa there was a preferential accumulation of VIP to at least three times the concentration of any of the other peptides. Our results suggest that all preproVIP-derived peptides are present and processed in the sphenopalatine ganglion but that there is a selective accumulation of VIP in the nerve terminals. This indicates that VIP is physiologically the most important transmitter among the preproVIP-derived peptides in parasympathetic nerves originating in the sphenopalatine ganglion.     

Location of PHM/VIP mRNA in human gastrointestinal tract detected by in situ hybridization

The expression of the gene for vasoactive intestinal polypeptide (VIP) and peptide histidine methionine (PHM) in the human gastrointestinal tract was studied by in situ hybridization and Northern blotting for PHM/ VIP mRNA and immunocytochemistry using specific antisera against the bioactive peptides PHM and VIP. In the colon sigmoideum, antisera against all five putative processing products of the VIP precursor (prepro-VIP) were used, namely prepro-VIP 22–79, PHM, prepro-VIP 111–122, VIP and prepro-VIP 156–170. Furthermore, RNA extracted from various regions of the gastrointestinal tract was examined by Northern blots and hybridization to a VIP-cDNA probe. Throughout the gastrointestinal tract, PHM/VIP mRNA was found in neurons only. Using single-or double-staining methods, we demonstrated both PHM/VIP mRNA and the corresponding peptides PHM and VIP in the neurons. In the sigmoideum, the single-staining methods were extended to investigate whether the neurons simultaneously contained PHM/VIP mRNA and each of the five prepro-VIP-derived peptides. Only one major band of PHM/VIP mRNA (1.9 kb) was found by Northern blotting in the tissue of the gastrointestinal tract.     

Immunochemical study on PHI/PHM with use of synthetic peptides

We have synthesized PHI and PHM (human PHI) as well as their fragments, PHI (1-6), PHI (1-15), PHI (14-19), PHI (14-27), PHI (20-27), PHM (1-15) and PHM (13-27), by the solution or solid-phase method for peptide synthesis. Using the highly purified synthetic peptides as immunogens or haptenic immunogens, five kinds of PHI/PHM specific antisera were produced. The major antibody-recognition sites of the five antisera were located respectively in the PHI C-terminal (R8201), in the PHI N-terminal (R8403), in the PHM C-terminal (R8502), and in the PHM whole molecule (R8702 and R8703). Radioimmunoassays (RIAs) with antisera R8201, R8403 and R8502, respectively, showed a wide distribution of immunoreactive (IR) PHI/PHM in porcine and human gastrointestinal and brain tissues. The concentrations of IR-PHI in the porcine gastrointestinal tissues, however, differed between the R8201 and R8403 RIAs employed for measurement. By using these two different PHI RIAs, the IR-PHI in the porcine brain tissue extract was shown to be almost a single component coeluting with synthetic PHI in gel filtration. The IR-PHI in the extract of porcine lower intestine on the other hand, contained, besides a PHI-like component, unidentified component(s) eluting immediately after synthetic PHI in gel filtration; this crossreacted with the PHI C-terminal specific R8201 antiserum but not with the N-terminal specific R8403 antiserum, suggesting the presence of the C-terminal-related fragment(s) of PHI in the tissues.     

Characterization of a novel prepro VIP derived peptide

A newly identified, large molecular weight form of peptide histidine methionine (PHM), has been found not only where it was first revealed, in the stomach, but also in high concentrations in the nasal mucosa and urogenital system, though not in the central nervous system, intestine and lung. An antibody to the spacer peptide sequence prepro-VIP 111-122, lying between PHM and VIP, also reacts directly with the large molecular form of PHM. It is suggested that the post-translational processing of prepro-VIP differs between tissues and in some, cleavage may not occur at the C-terminal end of PHM. The biological significance of this is currently unclear.     

Peptide histidine methionine and vasoactive intestinal peptide: occurrence and relaxant effect in the human female reproductive tract

The occurrence of the neuropeptides peptide histidine methionine (PHM) and vasoactive intestinal peptide (VIP) in the human female genital tract was studied by means of immunochemistry and radioimmunoassay in combination with gel chromatography. In addition, the effect of PHM and VIP on smooth muscle activity was investigated in vitro. The regional distribution of PHM as determined by radioimmunoassay correlated with that of VIP. This finding agreed with the immunohistochemical data, which, in addition, provided evidence for colocalization of the two peptides in nerve fibers. These fibers were most abundant in the vagina and the uterine cervix, where they seemed to innervate blood vessels, smooth muscle, and epithelial cells. The concentrations of immunoreactive PHM and VIP were found to be similar in all areas except in the vagina, where the PHM concentration was fourfold that of VIP. Gel chromatography of vaginal extract revealed a high concentration of a C-terminally extended form of PHM, suggesting differential processing pathways of the VIP precursor. Both PHM and VIP inhibited, in a dose-dependent manner, the smooth muscle activity in strips from the Fallopian tube and the myometrium. Administered in combination, PHM and VIP had an additive effect and displayed the same efficacy as VIP alone, indicating that the peptides act via a common receptor.     

The processing of interleukin-1 beta studied with antibodies raised against synthetic peptides from the precursor N-terminal region

The exact sequence of events during processing of human interleukin-1 beta (IL-1 beta) and the fate of the N-terminal region are unknown. We have used anti-peptide sera specific for the precursor and mature regions of IL-1 beta to study biosynthesis. These were raised against peptides corresponding to amino acids 1-15, 17-32, and 43-54 of the precursor and a peptide corresponding to the C-terminal 33 amino acids of mature human IL-1 beta. Antiserum to the mature region peptide immunoprecipitated the 35-kD precursor from cell lysates and 17-kD mature IL-1 beta and a 31-kD protein from the culture supernatants from radiolabeled human peripheral blood monocytes stimulated with lipopolysaccharide (LPS). Antisera to peptides from the precursor region also immunoprecipitated the 35-kD IL-1 beta precursor but not the 31-kD or 17-kD forms. Of the precursor-specific sera, only antiserum to amino acids 1-15 specifically recognized any other proteins; a peptide of 18 kD and a low molecular weight peptide, both of which accumulated in the medium. The 18-kD protein was not recognized by any of the other antisera and is unlikely to be the N-terminal region of the precursor removed during processing. Pulse-chase experiments indicated that the 31-kD protein could be a processing intermediate and also that it was itself an end product along with full-length precursor. Only 17-kD mature IL-1 beta had biological activity.     

Peptide histidine methionine (PHM) increases ileostomy output

The human vasoactive intestinal peptide (VIP) gene also encodes peptides histidine methionine (PHM) which has substantial sequence homology with VIP. Both are present in nerve fibers in the human ileum and circulate in greatly increased concentrations in patients with the watery diarrhoea syndrome. We have infused PHM (23 pmol/kg/min) into 5 patients with ileostomies to determine the effect of PHM on human ileal output. Plasma PHM levels rose from 22 +/- 6 to 6013 +/- 874 pM (mean +/- S.E.M.) during PHM infusions and ileal output rose from 16 +/- 3 to 177 +/- 27 g/30 min (P less than 0.0001). PHM infusions also produced a significant fall in the percentage of solid material and a rise in the concentration of chloride in the ileal effluent. Mean plasma PHM concentrations during PHM infusions were equal to the highest levels seen in patients with the watery diarrhoea syndrome, so PHM may contribute to diarrhoea in this condition. Neuronal PHM may exert physiological control over ileal transport of water and electrolytes.     

Identification and distribution of immunoreactive peptide YY in the human, canine, and murine gastrointestinal tracts: species-related antibody recognition differences

A radioimmunoassay using two antisera (antibody 80 and antibody 213) from rabbits immunized with porcine peptide YY has been characterized for both sensitivity and specificity. To determine the distribution of peptide YY in the gut, fresh tissue specimens from the human and canine gut were separated into mucosal-submucosal and muscularis externa layers by microdissection. These tissues and transmural specimens from murine gut were acid-extracted and neutralized, followed by radioimmunoassay using each antiserum. Immunoreactive peptide YY in canine and murine gut was present in similar concentration and distribution using each antiserum, with highest concentrations in the mucosal-submucosal layer of the descending colon. Using antibody 213, immunoreactive peptide YY throughout the human gut was measured only at the lower detection limit of the radioimmunoassay. By contrast, using antibody 80, peptide YY in human gut was present in a distribution similar to canine and murine gut. Using antibody 80, one major immunoreactive species was identified with C18 reverse-phase high-performance liquid chromatography in extracts of human, canine, and murine colon. These results suggest species-related antibody recognition differences. The similar concentrations of peptide YY in canine and murine gut determined with the two antisera are consistent with the hypothesis that the amino acid sequences of canine and murine peptide YY are similar to porcine peptide YY. Using antibody 213, the low concentrations of immunoreactive peptide YY found in human gut are consistent with the hypothesis that human and porcine peptide YY have different amino acid sequences. Antisera prepared by immunization with porcine PYY must therefore be carefully characterized prior to studies using human sera or human tissue extracts.     

Production of VIP- and PHM (human PHI)-related peptides in human neuroblastoma cells

We demonstrated the production and release of a peptide structurally identical with porcine and bovine VIP-28 in human neuroblastoma NB-OK-1 cell line. In the cells, VIP-like immunoreactive (IR-VIP) components of 8 K dalton (Kd), 11 Kd, 18 Kd and 30 Kd were also detected and the 8 Kd and 18 Kd components were apparently released into the culture medium, indicating the possibility of less extended or limited processing of the VIP precursor in the cultured cells of tumor origin. The cells were also shown to produce, simultaneously with the VIP-28, a PHI/PHM-like immunoreactive (IR-PHI/PHM) component which coeluted with synthetic PHM-27, not PHI-27, in reverse-phase high performance liquid chromatography (HPLC). In addition to the PHM-27-like component, another IR-PHI/PHM component was detected in the cell extract which eluted in HPLC immediately before synthetic PHM-27 and crossreacted with PHI-27 amino-terminal specific antiserum but not with PHI-27 central-portion specific or PHM-27 carboxyl-terminal specific antiserum. The presence in NB-OK-1 cells of this IR-PHI/PHM component related to the amino-terminal portion of PHI/PHM suggested possible alternative(s) of post-translational processing of the VIP precursor in the cells in terms of the production of PHM-27-related peptides.     

Alternative processing pathways for preprovasoactive intestinal peptide in the enteric nervous system of the rat

In order to study biosynthetic processing of preprovasoactive intestinal peptide (prepro VIP) we have raised antisera to sequences that flank the biologically active peptides VIP and PHI (peptide with N-terminal His and C-terminal Ile). We have used these antisera in radioimmunoassays to identify the N-terminal flanking peptide (NFP) and C-terminal flanking peptide (CFP)-like immunoreactivities in rat brain and gastrointestinal tract. Concentrations of NFP-LI were similar to those of VIP in brain and throughout the gut. Concentrations of CFP-LI were 10-20% those of VIP-LI but could be increased 5-fold by digestion with carboxypeptidase B, suggesting that the C-terminal lysine residue of prepro VIP is not normally removed during processing. In rat stomach the NFP-LI was of higher molecular weight and greater hydrophobicity than the intestinal component. The data are consistent with alternative processing pathways for prepro VIP in enteric nerves of rat stomach and intestine.     

Mapping of epitopes recognized by alloreactive cytotoxic T lymphocytes using inhibition by MHC peptides

To identify epitopes recognized by alloreactive CTL we have examined H-2Kb-specific CTL for their recognition of synthetic peptides with sequences derived from the native Kb class I molecule. Consecutive nested peptides spanning the immunogenic alpha 1 and alpha 2 domains of Kb were tested for their capacity to inhibit CTL clones in their recognition of cells expressing the native Kb molecule. Inhibition by these peptides was found to be an extremely rare event. One peptide (Kb.111-122) did inhibit recognition by one particular CTL clone, clone 13. Upon further investigation it was observed that clone 13 also recognized peptide Kb.111-122 when presented in the context of the syngeneic MHC molecule, Kd. Considering that residues 111 to 122 are located at the base of the antigen groove, and clone 13 is able to recognize Kb.111-122 when presented by syngeneic target cells, we suggest that inhibition of this CTL clone may be due to MHC restricted, self-presentation of peptide rather than to direct binding of free peptide to the TCR. Taken together, these results suggest inhibition of allospecific CTL by MHC peptides is a rare event at least for Kb recognition. Furthermore, they demonstrate the need for caution when interpreting inhibition by peptide as evidence for recognition by the TCR of the corresponding region on the native molecule.     

Identification of proNeuropeptide FFA peptides processed in neuronal and non-neuronal cells and in nervous tissue.

Peptides which should be generated from the neuropeptide FF (NPFF) precursor were identified in a neuronal (human neuroblastoma SH-SY5Y) cell line and in COS-7 cells after transient transfection of the human proNPFFA cDNA and were compared with those detected in the mouse spinal cord. After reverse-phase high performance liquid chromatography of soluble material, NPFF-related peptides were immunodetected with antisera raised against NPFF and identified by using on-line capillary liquid chromatography/nanospray ion trap tandem mass spectrometry. Neuronal and non-neuronal cells generated different peptides from the same precursor. In addition to NPFF, SQA-NPFF (Ser-Gln-Ala-Phe-Leu-Phe-Gln-Pro-Gln-Arg-Phe-amide) and NPAF were identified in the human neuroblastoma while only NPFF was clearly identified in COS-7 cells. In mouse, in addition to previously detected NPFF and NPSF, SPA-NPFF (Ser-Pro-Ala-Phe-Leu-Phe-Gln-Pro-Gln-Arg-Phe-amide), the homologous peptide of SQA-NPFF, were characterized. These data on intracellular processing of proNeuropeptide FFA are discussed in regard to the known enzymatic processing mechanisms.     

Peptide immunocytochemistry in afferent neurons from lower gut in rats

Several peptides were detected in primary sensory neurons located in nodose and dorsal root ganglia and projecting from rat cecum and rectosigmoid, through a combination of retrograde staining by the fluorescent tracer DY-2HCl and of the immunofluorescent procedure of Coons. The three larger cell populations thus identified stored immunoreactive components respectively similar to calcitonin gene-related peptide (CGRP), substance P (SP), and a peptide related to peptide histidine methionine (PHM). The later immunoreactivity consisted of a single molecular form with an apparent molecular weight smaller than PHM itself. Fewer cells contained components immunologically similar to somatostatin 14 (ST14), to the 1-14 N-terminal sequence of somatostatin 28 (1-14 S28), and to neuropeptide Y (NPY). Neonatal treatment with capsaicin resulted in a drastic reduction of immunoreactivity for SP, PHM, ST14, 1-14 S28, and in a partial reduction of CGRP-like positive perikarya. These results demonstrate that several peptides are potentially involved in the sensory innervation of the lower gut in rat.     

Ligand-induced structural constraints in human dihydrofolate reductase revealed by peptide-specific antibodies

Peptides from human dihydrofolate reductase (DHFR) generated by cyanogen bromide cleavage and corresponding to residues 15-52, 53-111, 112-125, and 140-186 (carboxyl terminus) were purified and used to immunize rats. Titration of the immune sera against denatured human DHFR by solid-phase immunoassay showed that peptides 15-52 and 140-186 were relatively highly immunogenic, unlike the native enzyme which is most immunogenic in the sequence 53-111. The antisera were specific for the corresponding peptides used for immunization. Antibodies to peptides 15-52, 53-111, and 140-186 cross-reacted with native human DHFR in solution in competition assays. However, the binding of nicotinamide adenine dinucleotide phosphate (reduced) (NADPH) and the inhibitors folate and methotrexate, both in binary and in ternary complexes with the enzyme, caused a striking reduction in binding of antibody. Using a sensitive radioactive assay, it was found that antisera to peptides 15-52 and 140-186, both of which exhibited a high antibody titer, caused significant inhibition of DHFR. Because peptide 140-186 does not include any active-site residues, it is concluded that at least in this case all the antibodies bound to regions outside the active site. Since comparison of the X-ray structures of the chicken liver DHFR holoenzyme with the apoenzyme reveals no changes in secondary structural elements (alpha-helices and beta-sheets), the reduction in antibody binding to DHFR-ligand complexes must not involve epitopes within these structures.(ABSTRACT TRUNCATED AT 250 WORDS)     

VIP and PHM and their role in nonadrenergic inhibitory responses in isolated human airways

There is increasing evidence in many species that vasoactive intestinal peptide (VIP) may be a neurotransmitter in nonadrenergic inhibitory nerves. We have studied the effect of electrical field stimulation (EFS), exogenous VIP, and isoproterenol (Iso) on human airways in vitro. We have also studied a related peptide, peptide histidine methionine (PHM), which coexists with VIP in human airway nerves, and in separate experiments studied fragments of the VIP amino acid sequence (VIP1-10 and VIP16-28) for agonist and antagonist activity. Human airways were obtained at thoracotomy and studied in an organ bath. In bronchi EFS gave an inhibitory response that was unaltered by 10(-6) M propranolol but was blocked by tetrodotoxin, whereas in bronchioles there was little or no nonadrenergic inhibitory response. VIP, PHM, and Iso all caused dose-dependent relaxation of bronchi, VIP and PHM being approximately 50-fold more potent than Iso. VIP, but not Iso, mimicked the time course of nonadrenergic inhibitory nerve stimulation. In contrast bronchioles relaxed to Iso but not to VIP or PHM. Neither propranolol nor indomethacin altered the relaxant effects of VIP or PHM, suggesting a direct effect of these peptides on airway smooth muscle. Neither of the VIP fragments showed either agonist or antagonist activity. We conclude that VIP and PHM are more potent bronchodilators of human bronchi than Iso and that the association between the relaxant effects of these peptides and nonadrenergic inhibitory responses suggests that they may be possible neurotransmitters of nonadrenergic inhibitory nerves in human airways.     

Naturally occurring products of proglucagon 111-160 in the porcine and human small intestine

Recent studies have revealed that the glucagon gene is expressed in the mammalian intestine. Here it codes for "glicentin" (proglucagon 1-69) and a glucagon-like peptide, proglucagon 78-107, recently isolated from porcine intestine. We studied the fate of the remaining COOH-terminal part of proglucagon (proglucagon 111-160) using radioimmunoassays against proglucagon 111-123 and 126-160. Two peptides were isolated from acid ethanol extracts of porcine ileal mucosa and sequenced: one corresponding to proglucagon 126-158 and one probably corresponding to proglucagon 111-158. By comparing human and porcine proglucagon sequences, Ala117 is replaced by Thr, and Ile138, Ala144, Ile152 and Gln153 are replaced by Val, Thr, Leu, and His. By gel filtration and radioimmunoassay of intestinal extracts it was established that a large part of porcine and virtually all of human proglucagon are processed to release proglucagon 111-123 (designated spacer peptide 2), which, like proglucagon 126-158 must be considered a potential hormonal entity. By isocratic high pressure liquid chromatography human spacer peptide 2 was indistinguishable from synthetic proglucagon 111-122 amide, suggesting that this is the structure of the naturally occurring human peptide.     

Evidence for common precursors but differential processing of VIP and PHM in VIP-producing tumors

To elucidate the biosynthesis of vasoactive intestinal polypeptide (VIP) and investigate the suggestion that the prepro-VIP contains another peptide designated PHM (the peptide with N-terminal histidine and C-terminal methionine amide) in its sequence, the concentration and molecular forms of immunoreactive VIP and PHM in 14 human VIP producing tumors (VIP-omas) were determined. Elevated quantities of both peptides were found in all tumor extracts but the concentration of PHM did not correlate with that of VIP and the ratio VIP/PHM varied from 0.5 to 8.5. Gel chromatography showed that in addition to peaks corresponding to VIP and PHM, two larger molecular forms with Kd values of 0.31 and 0.36 which displayed both VIP and PHM immunoreactivity were present. While the proportions between the various PHM molecular forms varied considerably, the relative contribution of the VIP immunoreactive peaks was rather constant from tumor to tumor. The molecular pattern was unaffected by protein denaturing with guanidine hydrochloride and cleavage of sulfide bonds with dithiothreitol. The findings indicate that VIP and PHM are co-produced in VIP-omas probably from common larger molecular forms and that differences in the post-translational processing between tissues exist.     

Characterization of the C-terminal flanking peptide of human beta-preprotachykinin

The nucleotide sequence of cDNA encoding the common biosynthetic precursor of substance P, neurokinin A and neuropeptide K (beta-preprotachykinin) predicts that, in the human, the precursor contains a C-terminal flanking peptide of 19 amino acid residues [beta-preprotachykinin(111-129)-peptide]. Using an antiserum raised against synthetic human beta-preprotachykinin(117-126)-peptide in radioimmunoassay, we have demonstrated that an extract of a human neuroendocrine tumor of the adrenal medulla contained approximately equimolar concentrations of C-terminal preprotachykinin immunoreactivity (C-PPT-IR), substance P and neurokinin A. The C-terminal preprotachykinin flanking peptide was purified to homogeneity and its primary structure was determined. The amino acid sequence of the peptide, Ala-Leu-Asn-Ser-Val-Ala-Tyr-Glu-Arg-Ser-Ala-Met-Gln-Asn-Tyr-Glu, indicates identity with beta-preprotachykinin(111-126)-peptide. The data suggest that the C-terminal flanking peptide, like the tachykinins, is packed into secretory storage vesicles but the Arg127-Arg128-Arg129 residues in human beta-preprotachykinin are removed from the peptide by the action of endogenous processing enzyme(s).