Evidence that the chromogranin B fragment 368-417 extracted from a pheochromocytoma is phosphorylated.

A rabbit antiserum was raised against a synthetic peptide corresponding to residues 403 to 417 of human chromogranin B. This peptide was chosen to match the potential C-terminal end of a putative proteolytic fragment of the protein located between dibasic doublets in positions 366-367 and in positions 418-419 of the precursor. A radioimmunoassay based on this antiserum was developed and used to detect the protein or a fragment thereof in a pheochromocytoma tumor extract. One fragment was purified to homogeneity by successive reverse-phase HPLC chromatographies. The N-terminal sequence established by automated Edman degradation, was N-Y-P-S-L-E-L-D-K-M-A-H-G-Y-G-E-E-S-E-E-E-R corresponding to the 368-389 sequence of human chromogranin B. Taking into account the specificity of the antiserum used for peptide identification and alignment with the precursor sequence, we deduced that the purified peptide was chromogranin B (368-417) and represented a new peptide generated by limited proteolysis of chromogranin B. Combining electrospray mass-spectrometry and enzymatic dephosphorylation, we demonstrated that this peptide was phosphorylated.

Evidence that the lizard helospectin peptides are O-glycosylated.

Six forms of helospectin (a vasoactive intestinal peptide analogue) were purified from the venom of the Heloderma horridum lizard. Their identification was performed by combining sequencing by automated Edman degradation and electrospray mass spectrometry analysis on the complete peptides and their tryptic fragments. The products resulting from the action of an O-glycosidase were also analysed. Two forms were identified as the previously named Hs1 and Hs2 of 38 and 37 amino-acid residues, respectively. Two forms corresponded to Hs1 and Hs2 O-glycosylated by a N-acetylhexosamine-hexose motif attached to the Ser32 residue. Two other forms were not completely characterized but might correspond to the O-glycosylated forms bearing a phosphate or a sulfate group. The glycosylation did not affect the capacity of the helospectins to recognize and to activate the human and the rat VPAC1 and VPAC2 receptors.

Isolation and primary structure of the CCI papain-like cysteine proteinases from the latex of Carica candamarcensis hook.

The dried latex of the mountain papaya, Carica candamarcensis, was chromatographed on CM-Sephadex C50, giving rise to three peaks (CCI, CCII and CCIII) with amidase activity on N-alpha-benzoyl-DL-arginine-4-nitroanilide. The less basic, most active, peak, CCI, was separated into two components, CCIa and CCIb, by reverse-phase HPLC under denaturing conditions. The primary structures of CCIa and CCIb are presented. They were deduced from sequence analysis of the whole proteins and peptides resulting from enzymatic digestions. Both proteinases are made of 213 amino acid residues, CCIb sharing 88-89% similarity with the three subvariants (G90/R212, E90/R212, E90/K212) of CCIa. 139-140 amino acid residues (65.8%) of CCIa and 141 residues (66.5%) of CCIb are common to papain. The seven cysteine residues are aligned with those of papain and the catalytic triad (Cys25, His159, Asn175) of all cysteine peptidases of the papain family is conserved. The similarity with the other cysteine proteases from Carica papaya is discussed.

Analogues of VIP, helodermin, and PACAP discriminate between rat and human VIP1 and VIP2 receptors.

Vasoactive intestinal polypeptide (VIP) acts through interaction with two subclasses of seven transmembrane G protein-coupled receptors named VIP1 and VIP2 receptors. These receptors have been cloned in different species, such as rat and human. Considering the different distribution of both receptor subclasses, there is considerable interest in the development of selective agonists and antagonists. The present study compares the binding properties of VIP, PACAP, GRF, secretin, and helodermin analogues on recombinant rat and human VIP1 and VIP2 receptors. On both rat and human receptors, secretin and GRF had a higher affinity for the VIP1 receptor subtypes. The amino-shortened VIP, and the carboxy terminal-shortened VIP and PACAP analogues also presented a higher affinity for the VIP1 receptor. PHI, PHV, helodermin, and helospectin were selective for the human VIP2 receptor subtypes. These results suggest that the helical structure of the carboxy terminal end is necessary for VIP2 recognition. The differences between species were the following: PHI, PHV, helodermin, and helospectin had a higher affinity for the rat VIP1 receptor than for the human VIP1 receptor. On both rat and human receptors, D-Ala4 VIP and D-Phe4 VIP had a high affinity for the VIP1 receptor and a low affinity for the VIP2 receptor. Thus, three domains of the ligand involved in VIP1/VIP2 receptor discrimination were identified: the amino acid residue in position 4 ([D-Ala4], [D-Phe4]VIP), in positions 8 and 9 (the effects of helodermin and helospectin), and the carboxy terminal end (the effects of the shortened VIP and pituitary adenylate cyclase activating polypeptide analogues).

Vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase-activating peptide (PACAP-27, but not PACAP-38) degradation by the neutral endopeptidase EC 3.4.24.11.

VIP (vasoactive intestinal polypeptide) and PACAP (pituitary adenylate cyclase-activating polypeptide), which are potent relaxing agents in the airways, were submitted to in vitro degradation by the neutral endopeptidase EC 3.4.24.11 (NEP), one of the most active peptidase in the lung, to test their relative resistance to proteolysis. Both VIP and PACAP(1-27) were cleaved by NEP, but PACAP(1-38) was not. The main fragments produced were VIP(1-22) and VIP(1-25), and PACAP(1-22) and PACAP(1-25), respectively. The degradation of VIP(1-27), PACAP(6-27), and PACAP(13-27) was also hindered by extending their C-terminal ends with the (28-38) sequence of PACAP(1-38). The sensitivity to enzyme degradation was gradually reduced when the C-terminal extension was increased from PACAP(1-27) to PACAP(1-29), PACAP(1-32) and PACAP(1-38). The biological activities of the degradation products were evaluated on the three classes of PACAP/VIP receptors, with VIP(1-25) and PACAP(1-25) retaining an important part of their activities on the VIP1 receptor. Thus, the degradation of VIP and PACAP(1-27) by the neutral endopeptidase 24.11 might produce a VIP1 receptor-selective active metabolite, provided that very high VIP or PACAP(1-27) concentrations are achieved in the receptor vicinity.

The long-acting vasoactive intestinal polypeptide agonist RO 25-1553 is highly selective of the VIP2 receptor subclass.

RO 25-1553 is a synthetic VIP analogue that induced a long-lasting relaxation of tracheal and bronchial smooth muscles as well as a reduction of edema and eosinophilic mobilization during pulmonary anaphylaxis. In the present study, we tested in vitro the capacity of RO 25-1553 to occupy the different VIP/PACAP receptor subclasses and to stimulate adenylate cyclase activity. The cellular models tested expressed one single receptor subtype: Chinese hamster ovary (CHO) cells transfected with the rat recombinant PACAP I, rat VIP1, and human VIP2 receptors; SUP T1 cells expressing the human VIP2 and HCT 15 and LoVo cells expressing the human VIP1 receptor. RO 25-1553 was threefold more potent than VIP on the human VIP2 receptor, 100- and 600-fold less potent than VIP on the rat and human VIP1 receptors, respectively, and 10-fold less potent than VIP and 3000-fold less potent than PACAP on the PACAP I receptor. RO 25-1553 was a full agonist on the VIP2, the PACAP I, and the rat recombinant VIP1 receptor but a partial agonist only on the human VIP1 receptor. Thus, RO 25-1553 is a highly selective agonist ligand for the VIP2 receptor subclass.

Development of high affinity selective VIP1 receptor agonists.

The biological effects of VIP are mediated by at least two VIP receptors: the VIP1 and the VIP2 receptors that were cloned in rat, human and mice. As the mRNA coding for each receptor are located in different tissues, it is likely that each receptor modulates different functions. It is therefore of interest to obtain selective agonists for each receptor subtype. In the present work, we achieved the synthesis of two VIP1 receptor selective agonsits derived from secretin and GRF. [R16]chicken secretin had IC50 values of binding of 1,10,000, 20, and 3000 nM for the rat VIP1-, VIP2-, secretion- and PACAP receptors, respectively. This peptide, however, had a weaker affinity for the human VIP1 receptor (IC50 of 60 nM). The chimeric, substituted peptide [K15, R16, L27]VIP(1-7)/GRF(8-27) had IC50 values of binding of 1,10,000, 10,000 and 30,000 nM for the rat VIP1-, VIP2-, secretin- and PACAP receptors, respectively. Furthermore, its also showed an IC50 of 0.8 nM for the human VIP1 receptor and a low affinity for the human VIP2 receptor. It is unlikely that this GRF analogue interacted with a high affinity to the pituitary GRF receptors as it did not stimulate rat pituitary adenylate cyclase activity. The two described analogues stimulated maximally the adenylate cyclase activity on membranes expressing each receptor subtype.

Carica papaya latex is a rich source of a class II chitinase.

A class II chitinase is present in the latex of the tropical species Carica papaya. The enzyme may be readily purified by using a combination of hydrophobic interaction- and cation-exchange chromatography. This enzyme preparation is homogeneous with respect to the three physico-chemical criteria of charge, M(r) (28,000) and hydrophobicity. It is also completely free of any proteolytic and bacteriolytic activities. The enzyme was classified as a class II chitinase on the basis of its N-terminal amino acid sequence up to the 30th residue. In agreement with this classification, the enzyme preparation hydrolyses chitinase substrates only very slowly and several free thiol functions are present in the polypeptide chain. These free thiol functions are buried, and to be available for titration with 2,2'-dipyridyldisulphide, the enzyme must be denatured. Unfolding of papaya chitinase requires particularly drastic conditions, not less than 4 M guanidinium hydrochloride at 25 degrees and pH 6.8.

Effect of introduction of an arginine16 in VIP, PACAP and secretin on ligand affinity for the receptors.

Rabbit secretin, which differs from all other mammalian secretins in having a Leu residue in position 6 (instead of Phe) and a basic residue (Arg) in position 16, had a lower affinity than porcine secretion on recombinant rat secretin receptors but had a greater affinity than porcine secretin on recombinant rat VIP1 and PACAP I receptors. Synthetic [L6] porcine secretin had a reduced potency on secretin and VIP1 receptors whereas [R16] porcine secretin had a similar binding profile as rabbit secretin. Thus, an arginine residue in position 16 reduced 3-fold the affinity of secretin for secretin receptors but increased 30-fold its affinity for the VIP1 and PACAP I receptors. The introduction of an arginine residue in position 16, instead of glutamine, in VIP and PACAP had a similar effect: [R16] VIP and [R16] PACAP had 3- to 10-fold higher affinities than VIP and PACAP for VIP1 and PACAP I receptors, and 3-fold lower affinities for the secretin receptors. The three [R16] peptides also had a reduced potency on the chimeric receptor consisting of the N-terminal part of the secretin receptor grafted on the VIP1 receptor, and an enhanced potency on the chimeric receptor consisting of the N-terminal part of VIP1 receptor grafted on the secretin receptor, indicating that position 16 of each ligand interacted with the N-terminal extracellular domain of the receptors.

Addition of the (28-38) peptide sequence of PACAP to the VIP sequence modifies peptide selectivity and efficacy.

Chimeric peptides were synthesized by adding the C-terminal extension 28-38 of the pituitary adenylate cyclase activating polypeptide (PACAP) to the sequences (1-27), (2-27), (3-27) and (6-27) of VIP. The capacity of these peptides to occupy the selective PACAP- and the non-selective PACAP-VIP receptors and to stimulate adenylate cyclase activity was studied in chinese hamster ovary (CHO) cells expressing the recombinant receptors. The results were compared to those obtained with VIP and the corresponding VIP fragments. The presence of the (28-38) PACAP extension increased at least 100-fold the VIP- or VIP fragment affinities for the selective PACAP receptor but not for the non-selective PACAP-VIP receptors. Furthermore, on both receptors, the extension increased peptide intrinsic activity: VIP(3-28) was a partial agonist while VIP(3-27)/PACAP(28-38) was as potent as VIP and was apparently a full agonist; VIP(6-28) had no intrinsic activity, but VIP(6-27)/PACAP(28-38) was a partial agonist. These results suggest: (1) the presence of a specific domain for the (28-38) PACAP sequence on the selective PACAP receptor; and (2) a stabilizing effect of the (28-38) PACAP sequence on the structure of N-terminally truncated VIP.

Interaction of amino acid residues at positions 8-15 of secretin with the N-terminal domain of the secretin receptor.

The ability of secretin, PACAP-(1-27)-peptide, and ten hybrid peptides to recognize and activate the rat secretin and vasoactive intestinal polypeptide (PACAP type II VIP1) receptors was tested on recombinant Chinese hamster ovary (CHO) cell lines. PACAP had a 2500-fold lower affinity than secretin for the secretin receptor, and secretin had a 300-fold lower affinity than PACAP for the VIP1 receptor. Amino acids 8, 13, and 15 of the PACAP molecule contributed significantly to the low affinity of PACAP for the secretin receptor. The amino acids at positions 5, 9, 10, 15, 16, and unidentified amino acid(s) between positions 17-20 made limited contributions to the low affinity of secretin for the VIP1 receptor. To identify the receptor region that interacts with these amino acids, we constructed chimeric receptors, which consist either of the N-terminal extracellular part of the secretin receptor and the core of the VIP1 receptor (N-Sn/VIP1r) or the N-terminal extracellular part of the VIP1 receptor and the core of the secretin receptor (N-VIP1/Snr), and tested the ability of the hybrid ligands to activate the adenylate cyclase of CHO cells expressing these chimeric receptors. The N-Sn/VIP1 receptors had a higher affinity for secretin than for PACAP. The hybrid peptide 6 that consists of the PACAP-(1-8)-Sn-(9-15)-PACAP-(16-27)-peptide sequence had a 30-fold to 200-fold higher potency than either parent peptide for the chimeric receptor, which suggests that while the N- and/or C-terminal part of the peptide interact with the transmembrane domain of the receptor, the discriminator region 9-15 recognizes the extracellular N-terminal domain of the receptor. This was confirmed by the observation that, out of all the peptides tested, hybrid 6 had the weakest potency for activation of the N-VIP1/Sn chimeric receptors.

Binding of the labelled muscarinic toxin 125I-MT1 to rat brain muscarinic M1 receptors.

The green mamba (Dendroaspis angusticeps) "muscarinic toxin', MT1, was radioiodinated by the chloramine T method. 125I-MT1 labelled the muscarinic M1 receptor subtype with a very good selectivity in rat brain. It had no preference for the receptor states with high or low affinity for agonists, and was not affected by Gpp(NH)p addition to the incubation medium. The 125I-MT1 binding was reversible, with a half life of 45 min at 25 degrees C. The effect of competitive and allosteric muscarinic antagonists on 125I-MT1 binding and dissociation can be rationalized by assuming that the radioiodinated toxin is able to label the muscarinic (acetylcholine) binding site.

C-terminally shortened pituitary adenylate cyclase-activating peptides (PACAP) discriminate PACAP I, PACAP II-VIP1 and PACAP II-VIP2 recombinant receptors.

Pituitary adenylate cyclase-activating polypeptide (PACAP) analogues were tested for their ability to occupy the recombinant selective PACAP receptors (PACAP type I receptors) and the non-selective PACAP-vasoactive intestinal polypeptide (VIP) receptors (PACAP type II, VIP1 and PACAP type II, VIP2 receptors), stably transfected and expressed in Chinese hamster ovary cells. Their capacity to stimulate the adenylate cyclase activity was also measured. The synthetic analogues tested were peptides shortened at the carboxyl terminus by the removal of 1-4 amino acids (PACAP-26 to PACAP-23). All the peptides discriminated the 3 receptor subtypes and had the highest affinity for the VIP1 receptors, and the lowest affinity for the VIP2 receptors; PACAP-25 having the highest ability to discriminate the VIP1 and VIP2 receptors. All the peptides tested were full agonists on the PACAP I and VIP1 receptors; PACAP-25 and -26 were partial agonists on VIP2 receptors and may be appropriate tools to establish the receptor subtype involved in a given cellular response.

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.

The C-terminus ends of secretin and VIP interact with the N-terminal domains of their receptors.

C-terminally truncated secretin and VIP molecules were synthesized, and their ability to occupy the recombinant secretin and VIP1 receptors stably expressed in Chinese hamster ovary (CHO) cells and to stimulate adenylate cyclase activity was studied. On secretin receptors, secretin (1-26) and secretin (1-24) were 10- and 50-fold less potent but as efficient as secretin (1-27); VIP (1-27) was as potent and efficient as VIP (1-28), and VIP (1-26) and VIP (1-25) were both 100-fold less potent. On VIP1 receptor, VIP (1-28) and VIP (1-27) were equipotent and VIP (1-26) and VIP (1-25) were 10- and 300-fold less potent, respectively; secretin (1-27) and secretin (1-26) were of equally low affinity and 10-fold more potent than secretin (1-24). Thus, the secretin and the VIP1 receptors had different selectivity profiles for the recognition of C-terminally truncated secretin and VIP derivatives. The chimeric receptors consisting in the N-terminal part of the secretin receptor on the core of the VIP1 receptor (N-Sn/VIP1.r) and in the N-terminal part of the VIP1 receptor on the core of the secretin receptor (N-VIP1/Sn.r) exhibited the selectivity pattern of the secretin and VIP1 receptors, respectively. The results suggest that the C-terminal end of secretin and VIP interacts with the N-terminal domain of the secretin and VIP receptors.

Fragments of pituitary adenylate cyclase activating polypeptide discriminate between type I and II recombinant receptors.

Pituitary adenylate cyclase activating polypeptide (PACAP) analogues were tested for their ability to occupy the recombinant selective PACAP receptors (PACAP type I receptor) or the non-selective PACAP-vasoactive intestinal polypeptide (VIP) receptors (PACAP type II, VIP1 and VIP2 receptors) stably transfected and expressed in Chinese hamster ovary (CHO) cells. The synthetic analogues consisted of N- and/or C-terminally shortened peptides. Thus, peptides starting at amino acid 1, 2, 3 or 6 and terminating at amino acid 27, 29, 30, 32 or 38 were compared on the three receptors studied. The shortening of PACAP-(1-38) to PACAP-(1-27) was of little influence. However, in N-terminally deleted peptides the PACAP-38 derivatives were of higher affinity than the PACAP-27 fragments on PACAP type I and PACAP type II, VIP2 receptors but not on PACAP type II, VIP1 receptors. The presence of the sequence 28-32 was in all cases sufficient to reproduce the data obtained with the PACAP-38 analogues. PACAP-(3-32) is able to discriminate the PACAP type II, VIP2 subtype from the other two subtypes, and PACAP-(6-30), PACAP-(6-32) and PACAP-(6-38) can discriminate the PACAP type II, VIP1 receptors from the other two subtypes. These molecules may help in the quantitative detection of receptor subclasses in complex systems when two or more receptor subtypes are found.

Purification and sequence determination of a new muscarinic toxin (MT4) from the venom of the green mamba (Dendroaspis angusticeps).

A toxin which partially inhibited [3H]N-methylscopolamine binding to rat brain muscarinic receptors was purified from the venom of green mamba, Dendroaspis angusticeps. The N-terminal sequence (up to 45 amino acids) was determined by automated Edman degradation of the whole molecule. The complete sequence was elucidated after enzymatic cleavage with endoproteinase Arg-C or endoproteinase Lys-C and peptide fragments purification. The identity of the C-terminal amino acid was confirmed by hydrazinolysis. The new toxin (MT4) had eight half-cystines and 66 amino acids. It differed from muscarinic toxin MT1 by a single substitution in position 57 (arginine in MT1, histidine in MT4), proximal to the sixth half-cystine.