Properties of vasoactive-intestinal-peptide receptors and beta-adrenoceptors in the murine radiation leukemia-virus-induced lymphoma cell line BL/VL3

1. Based on radioligand binding and adenylate cyclase activation, functional receptors to vasoactive intestinal peptide(VIP)/helodermin, were shown to coexist with beta 2-adrenoceptors and prostaglandin receptors in membranes from a cultured cloned BL/VL3 cell line of murine T-cell lymphoma induced by a radiation leukemia virus. 2. The relative potency of VIP-related peptides to stimulate adenylate cyclase activity was: helodermin greater than VIP greater than peptide histidine isoleucinamide. Five VIP analogs inhibited 125I-iodo-VIP binding and stimulated adenylate cyclase activity, their decreasing order of potency being: VIP greater than [D-Asp3]VIP greater than [D-Ser2]VIP greater than [D-Ala4]VIP = [D-His1]VIP = [D-Phe2]VIP. [D-Phe2]VIP acted as a partial agonist (with an intrinsic activity of 0.1 as compared to that of VIP = 1.0) and competitively inhibited helodermin- and VIP-stimulated adenylate cyclase activity with a similar Ki (0.07-0.10 microM). These data suggest the existence, in this murine T-cell lymphoma, of VIP receptors of the 'helodermin-preferring' subtype that are coupled to adenylate cyclase.     

Pharmacological characterization of VIP receptors in human lung membranes

The ability of VIP, PHI, secretin, helodermin, and seven N-terminally D-amino monosubstituted VIP and PHI analogs to occupy (125I)iodo-VIP labeled receptors and to activate adenylate cyclase was tested on human lung membranes purified by the method of Schachter et al. Best fitted Kd, Kact and % of max. values suggested the coexistence, in near equal proportions, of two classes of VIP-preferring binding sites coupled to adenylate cyclase that showed similar decreasing affinity for: VIP greater than (D-Ala4)-VIP greater than (D-Asp3)-VIP = (D-Ser2)-VIP greater than (D-His1)-VIP greater than PHI greater than (D-Phe2)-VIP greater than (D-Phe4)-VIP. (D-Arg2)-VIP was a non-selective agonist. A third receptor type, coupled to adenylate cyclase and showing high affinity for secretin and helodermin but not for VIP, was also detected.     

D-Phe4]peptide histidine-isoleucinamide ([D-Phe4]PHI), a highly selective vasoactive-intestinal-peptide (VIP) agonist, discriminates VIP-preferring from secretin-preferring receptors in rat pancreatic membranes

The capacity of vasoactive intestinal peptide (VIP), peptide histidine-isoleucinamide (PHI), secretin, and a series of analogs to discriminate between VIP-preferring and secretin-preferring receptors that coexist in rat pancreatic plasma membranes was evaluated by their ability to inhibit [125I]iodo-VIP and [125I]iodo-secretin binding and to activate adenylate cyclase. VIP, the VIP analogs [D-His1]VIP, [D-Ser2]VIP, [D-Asp3]VIP and [D-Ala4]VIP, PHI, [D-Phe4]PHI, and secretin inhibited the binding of both ligands in a concentration range of 10(-11) M to 10(-5) M and with a selectivity factor varying from 18,000 to 0.1. The only exception was [D-Phe4]PHI that inhibited 125I-VIP binding only, with an IC50 of 7 nM, and with no inhibition of 125I-secretin binding at 10 microM. The peptides tested stimulated adenylate cyclase in the same membranes and the slope of the dose-effect curves indicated that all peptides, except [D-Phe4]PHI, interacted with at least two classes of receptors: VIP-preferring and secretin-preferring receptors. By contrast, the dose-effect curve of [D-Phe4]PHI activation of adenylate cyclase was monophasic and competitively modified by [D-Phe2]VIP (a VIP antagonist) but not by secretin(7-27) (a secretin antagonist), indicating an interaction with VIP-preferring receptors only. Thus, [D-Phe4]PHI appears to be a highly selective tool to characterize these receptors.     

Pharmacological characterization of the novel helodermin/VIP receptor present in human SUP-T1 lymphoma cell membranes

[Acetyl-His1]VIP stimulated adenylate cyclase with higher potency than VIP in membranes from human SUP-T1 lymphoblasts and was used as an efficient radioiodinated ligand with low non-specific binding to evaluate the relationship between receptor occupancy and adenylate cyclase activation and the possible interference of peptide T (an epitope derived from HIV envelope protein gp120). Various peptides inhibited [125I-acetyl-His1]VIP binding and activated the enzyme, their order of potency being: helodermin greater than [acetyl-His1]VIP greater than VIP = PHI = [Phe1]VIP greater than [D-Phe2]VIP = [D-Ala4]VIP = [D-Phe4]PHI greater than or equal to [D-Phe4]VIP greater than [D-His1]VIP giving further support for the existence of a novel subtype of helodermin/VIP receptors. [D-Ala1]peptide T and VIP-(10-28) did not recognize the binding site and did not inhibit, even at high concentration, VIP - or VIP analogue - stimulated adenylate cyclase activities.     

A new type of functional VIP receptor has an affinity for helodermin in human SUP-T1 lymphoblasts

A new type of VIP receptor was characterized in human SUP-T1 lymphoblasts. The order of potency of unlabeled peptides, in the presence of [125I]helodermin, was: helodermin(1-35)-NH2 = helodermin(1-27)-NH2 greater than helospectin greater than VIP = PHI greater than [D-Ser2]VIP greater than [D-Asp3]VIP greater than [D-His1]VIP greater than or equal to [D-Ala4]VIP greater than or equal to secretin = GRF. This specificity was distinct from that of all VIP receptors described so far in that: (i) the affinity for helodermin (Kd = 3 nM) was higher than that of VIP (Kd = 15 nM) and PHI (Kd = 20 nM); and (ii) position 4 played an important role in ligand binding. The labeled sites were likely to be functional receptors as adenylate cyclase in crude lymphoblastic membranes (200-10,000 x g pellets) was stimulated by peptides, in the presence of GTP, with the following order of potency: helodermin(1-35)-NH2 greater than helodermin(1-27)-NH2 greater than helospectin = VIP = PHI.     

Receptor binding and adenylate cyclase activities of glucagon analogues modified in the N-terminal region

In this study, we determined the ability of four N-terminally modified derivatives of glucagon, [3-Me-His1,Arg12]-, [Phe1,Arg12]-, [D-Ala4,Arg12]-, and [D-Phe4]glucagon, to compete with 125I-glucagon for binding sites specific for glucagon in hepatic plasma membranes and to activate the hepatic adenylate cyclase system, the second step involved in producing many of the physiological effects of glucagon. Relative to the native hormone, [3-Me-His1,Arg12]glucagon binds approximately twofold greater to hepatic plasma membranes but is fivefold less potent in the adenylate cyclase assay. [Phe1,Arg12]glucagon binds threefold weaker and is also approximately fivefold less potent in adenylate cyclase activity. In addition, both analogues are partial agonists with respect to adenylate cyclase. These results support the critical role of the N-terminal histidine residue in eliciting maximal transduction of the hormonal message. [D-Ala4,Arg12]glucagon and [D-Phe4]glucagon, analogues designed to examine the possible importance of a beta-bend conformation in the N-terminal region of glucagon for binding and biological activities, have binding potencies relative to glucagon of 31% and 69%, respectively. [D-Ala4,Arg12]glucagon is a partial agonist in the adenylate cyclase assay system having a fourfold reduction in potency, while the [D-Phe4] derivative is a full agonist essentially equipotent with the native hormone. These results do not necessarily support the role of an N-terminal beta-bend in glucagon receptor recognition. With respect to in vivo glycogenolysis activities, all of the analogues have previously been reported to be full agonists.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of HIS1 modifications on the ability of vasoactive intestinal peptide to stimulate adenylate cyclase from rat and human tissues

The importance of the N-terminal His residue of VIP for stimulating adenylate cyclase was appreciated by estimating the intrinsic activity and EC50 of four VIP analogues on membranes from rat lung, liver, brain, anterior pituitary, and pancreas, and on human heart membranes. In all tissue preparations tested except one, the order of efficacy (and often potency) was: VIP greater than (Ac-His1)VIP greater than (Phe1)VIP = (3-Me-His1)VIP greater than (D-His1)VIP. In rat heart membranes, the order of efficacy was somewhat different: VIP greater than (Ac-His1)VIP = (Phe1)VIP greater than (D-His1)VIP greater than (3-Me-His1)VIP. These data demonstrated the key role of His1 in VIP in activating adenylate cyclase. They suggest that a given VIP analogue might act as full agonist in tightly coupled adenylate cyclase systems (such as those of rat lung and liver membranes) whereas the same analogue could not promote full activity in poorly coupled systems (such as that present in rat brain synaptic membranes).     

VIP and related peptides induce rapid homologous desensitization in the human lymphoma SUP T1 cell line

Incubation of human SUP T1 lymphoblasts with VIP, helodermin and related peptides induced homologous desensitization within 5 min as indicated by: 1) a secondary decrease in cellular cyclic AMP levels, even in the presence of phosphodiesterase inhibitors, 2) a reduced capacity of cells to bind [125I]helodermin, 3) decreased helodermin stimulation of adenylate cyclase activity in membranes, and 4) unaffected NaF- and Gpp[NH]p-stimulated adenylate cyclase activities. The desensitizing ability of all peptides correlated with their efficacy to occupy cell receptors, except for [D-Phe2]VIP, a partial VIP agonist with low intrinsic activity, that did not desensitize.     

Adenylate cyclase stimulation by VIP in rat and human parotid membranes

Adenylate cyclase activity was stimulated by vasoactive intestinal peptide (VIP) in rat parotid membranes, in the presence of 100 microM guanosine triphosphate (GTP). The threshold concentration of VIP was 300 nM and the activity doubled at the maximal VIP concentration tested (30 microM). The relative potency of peptides of the VIP family was: VIP greater than peptide histidine isoleucinamide (PHI) greater than secretin. The beta-adrenergic agent isoproterenol was a more efficient activator of rat parotid adenylate cyclase and its stimulatory effect, like that of VIP, depended on the presence of GTP. The effects of VIP and isoproterenol were both potentiated by 10 microM forskolin. By comparison with rat parotid preparations, membranes from a human parotid gland responded similarly to the VIP family of peptides (VIP greater than PHI greater than secretin). In both rat and human parotid membranes, two proteins (Mr 44 kDa and 53 kDa) of the alpha-subunit of Ns (the guanyl nucleotide-binding stimulatory protein) were labelled by ADP-ribosylation, in the presence of cholera toxin. Taken together, these results indicate that VIP receptors, when coupled to Ns, were able to activate the adenylate cyclase system in rat and human parotid membranes.     

Specificity of receptors to vasoactive intestinal peptide in guinea pig brain.

The specific binding of VIP to guinea pig brain membranes was tested by 1/ the ability of eight VIP and secretin analogs and fragments to inhibit the binding of ¹²⁵I-VIP and 2/ the capacity of the same peptides to influence basal and VIP-stimulated adenylate cyclase activities. Among all peptides tested, only VIP, secretin, [Val⁵] secretin, and [Gln⁹, Asn¹⁵] secretin (5–27) were able to inhibit ¹²⁵I-VIP binding. The adenylate cyclase activity was stimulated by VIP, secretin and [Val⁵] secretin. [Gln⁹, Asn¹⁵] secretin (5–27) although inactive per se was able to inhibit the VIP-stimulated adenylate cyclase activity competitively.     

Concentration-dependent inactivation of superoxide dismutase

1. Vasoactive intestinal peptide (VIP) receptors were identified in crude rat hepatic membranes by 125I-labelled VIP binding and by the ability of VIP to stimulate adenylate cyclase activity. The specificity of these receptors was evaluated by the capacity of secretin, synthetic secretin analogues, and secretin fragments to inhibit 125I-labelled VIP binding and to stimulate adenylate cyclase. 2. The results were compatible with the existence of two classes of VIP binding sites that could be distinguished according to their affinity for VIP and their specificity. High-affinity sites were more specific for VIP as secretin was 175 times less potent than VIP for recognition of these sites while being only 33 times less potent than VIP for recognition of low-affinity sites. 3. Secretin analogues, monosubstituted in position 2, 3, 4 or 6 were less potent than secretin for adenylate cyclase stimulation as well as for the recognition of the two classes of receptors. [Val5]secretin was more potent than secretin and appeared definitely more VIP-like than secretin; [Ala4, Val5] and [D-Ala4,Val5]secretin were equipotent to secretin. 4. The fragment secretin (7-27) was unable to recognize VIP receptors and to stimulate adenylate cyclase. The substituted fragment [Gln9,Asn15]secretin (5-27) recognized these receptors with weak potency but could not activate the enzyme.     

Structural requirements for the binding of the pituitary adenylate-cyclase-activating peptide to receptors and adenylate-cyclase activation in pancreatic and neuronal membranes

PACAP (pituitary adenylate-cyclase-activating peptide)-binding receptors were investigated in membranes from the rat pancreatic acinar cell line, AR 4-2J, the rat hippocampus and the human neuroblastoma cell line NB-OK, by 125I-PACAP(1-27) (amino acid residues 1-27 of N-terminal amidated PACAP) binding and adenylate cyclase activation. The relative binding of 125I-PACAP(1-27) to the receptor, and ability to activate adenylate cyclase were PACAP greater than or equal to PACAP(1-27) greater than PACAP(2-38) greater than PACAP(1-9)-VIP(10-28)(PACAP-VIP) greater than PACAP(2-27) greater than [Ser9,Tyr13]VIP greater than [Tyr13]VIP greater than or equal to [Ser9]VIP greater than or equal to VIP(1-23)-PACAP(24-27)(VIP-PACAP) greater than VIP (vasoactive intestinal peptide). The N-terminal moiety of PACAP(1-27) was more important than the three amino acids at the C-terminus for 125I-PACAP(1-27)-binding site recognition. For rat pancreatic 125I-VIP-binding sites tested with 125I-VIP, the order of binding affinity was PACAP = PACAP(1-27) greater than or equal to VIP = [Ser9]VIP = [Tyr13]VIP = [Ser9,Try13]VIP greater than or equal to PACAP-VIP greater than or equal to VIP-PACAP greater than PACAP(2-38) = PACAP(2-27). Pancreatic 125I-VIP-binding sites, when compared to 125I-PACAP(1-27)-binding sites, showed little specificity and only weak coupling, so that PACAP and VIP-PACAP acted only as partial VIP agonists on adenylate cyclase.     

Specific labelling by [125I]helodermin of high-affinity VIP receptors in rat liver membranes

Helodermin, a newly isolated peptide from Gila Monster venom, is structurally related to VIP and secretin. When used as radioligand, [125I]helodermin bound rapidly and reversibly to crude rat liver membranes, the dissociation being accelerated by GTP. Competition binding curves of [125I]helodermin and [125I]VIP with unlabelled peptides showed the following order of decreasing affinity: VIP greater than helodermin greater than secretin greater than hpGRF(1-29)-NH2. The shape of binding curves and of concurrent adenylate cyclase activation is compatible with the specific labelling, by [125I]helodermin, of a class of high-affinity VIP receptors that is capable to stimulate adenylate cyclase.     

Demonstration of [125I]VIP binding sites and effects of VIP on cAMP-formation in rat insulinoma (RINm5F and RIN14B) cells.

Vasoactive intestinal polypeptide (VIP)-immunoreactive nerves have been demonstrated in close association with the islets of Langerhans, and VIP has been shown to stimulate insulin and somatostatin secretion. Using [125I]VIP and membranes prepared from rat insulinoma (RIN) cells, i.e., the subclones m5F (m5F; mainly insulin-secreting) and 14B (14B; mainly somatostatin-secreting), it was found that VIP (10(-10)-10(-7) M) competitively inhibited the binding of [125I]VIP. A single class of high affinity binding sites with Kd values of 0.40 +/- 0.06 nM and 0.36 +/- 0.08 nM for m5F and 14B, respectively, with a corresponding number of binding sites (Bmax) of 163 +/- 20 and 254 +/- 51 fmol/mg protein was observed. The rank order of potency in inhibiting [125I]VIP binding was in both cell lines: VIP greater than helodermin greater than pituitary adenylate cyclase activating polypeptide 1-27 (PACAP27) greater than peptide histidine isoleucine (PHI) greater than secretin. VIP caused a dose-dependent increase in cAMP-formation in both m5F and 14B cell membranes with EC50 values of 3.0 and 3.5 nM, respectively, but VIP (1.10(-9)-3.10(-6) M) had no effect on insulin secretion (over 2 h) from the m5F cells. Thus, the data suggest that the VIP-receptors in these neoplastic rat cell lines, despite an apparent coupling to adenylate cyclase activity, seem to be functionally uncoupled to an effect on insulin secretion following an acute exposure to VIP.     

Interaction of GRF with VIP receptors and stimulation of adenylate cyclase in rat and human intestinal epithelial membranes. Comparison with PHI and secretin

GRF (10(-8) - 10(-5) M) is shown to inhibit competitively the binding of [125I]VIP to human and rat intestinal epithelial membranes. The affinity of GRF for VIP receptor is 700-800-times lower than that of VIP in both species. The order of affinity of different peptides is VIP greater than PHI greater than secretin greater than GRF in rat, and VIP greater than GRF greater than PHI greater than secretin in man. The important species specificity of VIP receptors in recognizing PHI and secretin does not occur in the case of GRF. GRF stimulates adenylate cyclase through its interaction with VIP receptors in rat and human membranes. However, while GRF behaves as a VIP agonist in human tissue, it is a partial agonist/antagonist of VIP in the rat.     

Phorbol ester induces loss of VIP stimulation of adenylate cyclase and VIP-binding sites in HT29 cells

Treatment of HT29 cells with the tumor promoting phorbol ester PMA resulted in an attenuation of VIP-stimulated cAMP production in intact cells and VIP-stimulated adenylate cyclase activity in cell membranes. PMA did not decrease the ability of cholera toxin and forskolin to elevate cAMP levels in intact cells. Fluoride-stimulated adenylate cyclase activity in HT29 cells homogenates was not affected by PMA. The maximal VIP binding capacity of homogenates prepared from HT29 cells treated with PMA was decreased by 50%. It is concluded that protein kinase C regulates VIP receptor function possibly through phosphorylation of the VIP receptor.     

Interaction of Gila monster venom with VIP receptors in intestinal epithelium of human. A comparison with rat

Gila monster venom (1-300 micrograms/ml) is shown to inhibit completely the binding of [125I]VIP to human and rat intestinal epithelial cell membranes. In both models, the venom inhibits [125I]VIP binding and stimulates adenylate cyclase with a maximal efficiency that is similar to that of VIP and a potency that is 10000-50000 times lower than that of the peptide, on a weight basis. At maximal doses, VIP and Gila monster venom do not exert an additive effect on adenylate cyclase, suggesting that the activation of the enzyme by the venom occurs through VIP receptors. As is the case for VIP, adenylate cyclase activation by Gila monster venom requires the presence of GTP in the incubation medium. Finally, no VIP-like immunoreactivity was detected in the venom using an antiserum raised against mammalian VIP. All these data suggest the presence in the venom of the Gila monster, of a new substance which behaves as a VIP agonist in human as well as rat intestine.     

Evidence that helodermin, a newly extracted peptide from Gila monster venom, is a member of the secretin/VIP/PHI family of peptides with an original pattern of biological properties

Helodermin, a newly isolated peptide from the venom of Gila monster (Heloderma suspectum) was shown to stimulate the adenylate cyclase activity of rat pancreatic membranes as efficiently as secretin and VIP. It also increased cyclic AMP levels and inhibited [125I]VIP binding in rat pancreatic acini. Finally, helodermin activated adenylate cyclase in membranes from rat heart, rat brain, and human heart, showing properties analogous yet distinct from those of secretin, VIP and PHI.     

Interaction of a bovine thymic peptide extract with vasoactive intestinal peptide (VIP) receptors

Bovine t hymic peptide extract (1–100 g/ml) is shown to completely inhibit the binding of [¹²⁵I]VIP to rat blood mononuclear cells, lymphoid cells of spleen, and liver plasma membranes. In the three models, the bovine thymic peptide extract inhibits [¹²⁵I]VIP binding with a potency that is 4000–7000 times lower than that of the native VIP, on a weight basis. In rat liver plasma membranes, the bovine thymic peptide extract stimulates adenylate cyclase with a maximal efficiency that is similar to that of VIP. At maximal doses, VIP and thymic peptide extract do not exert an additive effect on adenylate cyclase, suggesting that the activation of the enzyme by the bovine thymic peptide extract occurs through VIP receptors. Finally, no VIP-like immunoreactivity was detected in the thymic peptide extract using an antiserum raised against mammalian VIP. All these data suggest the presence in the bovine thymic peptide extract of a new substance which behaves as a VIP agonist in rat.