The ANF-C receptor is not linked to adenylyl cyclase inhibition in bovine pulmonary artery endothelial cells.

The possible inhibition of adenylyl cyclase activity by atrial peptides selective for the ANF-C receptor was investigated in bovine pulmonary artery endothelial cells. In these cells isoprenaline, guanine nucleotide and forskolin dose-dependently increased activity over basal levels. In the presence of rANF(99-126), these dose-dependent increases were not reduced, nor were they affected by the ANF-C receptor selective analogue C-ANF(102-121). Furthermore, the selective analogues rANF(103-123) and des[Cys105,Cys121]rANF104-126 had no effect on basal or stimulated adenylyl cyclase activity. It can be concluded that ANF-C receptors are not linked to inhibition of adenylyl cyclase in these cells.     

Differential antimitogenic effectiveness of atrial natriuretic peptides in primary versus subcultured rat aortic smooth muscle cells: Relationship to expression of ANF-C receptors

Previous studies have shown that atrial natriuretic peptides inhibit mitogenesis in subcultured aortic smooth muscle cells by a mechanism that appears to be mediated via the C-type or “clearance” receptor. In the current study, we have compared the antimitogenic effect of these peptides in serum-stimulated primary aortic smooth muscle cell cultures and in subcultured cells. A series of atrial peptides, including rANF_99–126, rANF_103–126, and rANF_103–125, were only poorly antimitogenic in serum-stimulated primary cultures, whereas des[Cys¹⁰⁵, Cys¹²¹] rANF_104–126 which binds selectively to the ANF-C receptors had no antimitogenic activity. In contrast, in subcultured cells (between subcultures 3 and 25), rANF_99–126, rANF_103–126, rANF_103–126, Cys¹¹⁶rANF_102–116, and des[Cys¹⁰⁵, Cys¹²¹]rANF_104–126 inhibited serum-induced [³H]thymidine incorporation (IC₅₀ in the range of 10–50 nM), with maximal inhibition of 40–70%. The lack of antimitogenic activity in primary cultures did not appear to be related to the lack of cGMP elevation elicited by atrial peptides or to an inherent insensitivity to the action of antimitogens, because primary cultures were responsive to the cGMP-elevating effect of atrial peptides and the cells were more rather than less sensitive to the antimitogenic effect of the nitric-oxide-vasodilator, SNAP, as compared to subcultured cells. Analysis of the affinity and binding capacity of freshly isolated aortic membranes, and primary or secondary cultures for [¹²⁵I]rANF_99–126, revealed that the number of ANF receptors increased by tenfold, following subculture. Moreover, subcultured cells contained receptors with increased binding affinity for peptide analogues selective for the ANF-C-type type receptor. Covalent cross-linking studies with (¹²⁵I)rANF_99–126 confirmed that membranes prepared from fresh aortae predominantly expressed the ANF-A/guanylate cyclase receptor, whereas in subcultured cells the predominantly cross-linked protein was the ANF-C-type receptor, with receptors in primary cultures occupying an intermediate position. These results suggest that the binding and antimitogenic activity of atrial peptides in aortic smooth muscle cells depends on the phenotypic state of these cells. Moreover, the increased antimitogenic potency of atrial peptides in secondary cultures may reflect increased expression of the ANF-C-type receptors. © 1993 Wiley-Liss, Inc.     

Atrial natriuretic factor recognizes two receptor subtypes in endothelial cells cultured from bovine pulmonary artery

In this study specific high affinity binding sites for atrial natriuretic factor (rANF(99-126] have been identified on cultured endothelial cells of bovine pulmonary artery origin (BPAEC). A time-dependent rise in cellular cGMP levels stimulated by rANF(99-126) was followed by release of the nucleotide into the incubation medium. The use of truncated, ring-deleted and linear atrial peptide analogs in competitive displacement analysis and measurement of cGMP accumulation indicated that only a minor proportion (5-11%) of the available receptor pool was of the ANF-B receptor subtype, linked to guanylate cyclase, with the remaining major proportion possibly of the ANF-C (clearance) receptor subtype. The existence of two ANF receptor subtypes in this cell culture model would suggest a significant role for the circulating peptide in modulation of pulmonary endothelial cell function, which would influence or complement its direct actions on the underlying vasculature of the pulmonary circulation.     

Vascular atrial natriuretic factor receptor subtypes are not independently regulated by atrial peptides

The regulation of the atrial natriuretic factor (ANF) receptor system in cultured rat vascular smooth muscle cells (RVSMC) was examined following long term pretreatment of these cells with rANF99-126 or with any one of a series of truncated and ring-deleted analogs. The latter analogs are reported to bind selectively the ANF-C or clearance receptor. Initial competition binding studies revealed that all analogs examined showed comparable apparent receptor binding affinities (Ki values did not differ by more than 10-fold). In contrast, the extent of interaction of the ANF analogs with the receptor pool coupled to particulate guanylate cyclase (the ANF-B receptor) was much more variable, with some ligands failing to stimulate cGMP production or particulate guanylate cyclase over the concentrations tested. Pretreatment of cells for 24 h with rANF99-126 or any of the truncated analogs that interact with the ANF-B receptor caused a dose- and time-dependent decrease in the number of ANF binding sites (99% of which are uncoupled in RVSMC) without any change in affinity. Examination of the binding activity following pretreatment of the cells with ANF suggested that the observed reduction in 125I-rANF99-126 binding capacity was not because of the retention of the peptide on its receptor. Furthermore, this down-regulation was associated with desensitization of particulate guanylate cyclase resulting in a decreased responsiveness of intracellular cGMP accumulation to ANF. In contrast, however, analogs selective for the ANF-C receptor pool failed to cause down-regulation or desensitization. These findings suggest that ANF-C receptors in RVSMC are not independently down-regulated by selective ligands but that nonselective analogs that down-regulate and desensitize the ANF-B receptor system can by some cooperative mechanism reduce the size of the predominant ANF-C receptor pool in these cells.     

Identification and characterization of atrial natriuretic factor receptors in the rat retina

The characteristics of atrial natriuretic factor (ANF) receptors where studied in rat retinal particulate preparations. Specific 125I-ANF binding to retinal particulate preparations was greater than 90% of total binding and saturable at a density (Bmax) of 40 +/- 8 fmol/mg protein with an apparent dissociation constant (Kd) of 6.0 +/- 2.0 pM (n = 3). Apparent equilibrium conditions were established within 30 min. The Kd value of 125I-ANF binding calculated by kinetic analysis was 4.0 pM. The Bmax of 60 +/- 10 fmol/mg protein and the Kd of 5 +/- 2 pM, calculated by competition analysis, were in close agreement with the values obtained from Scatchard plots or kinetic analysis. The 125I-ANF binding to retinal particulate preparations was not inhibited by 1 microM concentration of somatostatin, vasopressin, vasoactive intestinal peptide, adrenocorticotropin, thyrotropin releasing hormone, or leu-enkephalin. The rank order of potency of the unlabelled atrial natriuretic peptides for competing with specific 125I-ANF (101-126) binding sites was rANF (92-126) greater than rANF (101-126) greater than rANF (99-126) greater than rANF (103-126) greater than Tyro-Atriopeptin I greater than hANF (105-126) greater than rANF (1-126). Similar results have been obtained in peripheral tissues and mammalian brain, indicating that central and peripheral ANF-binding sites have somewhat similar structural requirements. Affinity cross-linking of 125I-ANF to retinal particulate preparations resulted in the labelling of two sites of molecular weight 140 and 66 kDa, respectively. This demonstration of specific high-affinity ANF receptors suggests that the peptide may act as a neurotransmitter or neuromodulator in the retina.     

Interactions between endothelin and atrial natriuretic factor in the rat aortic ring preparation.

The potential interaction (s) between atrial natriuretic factor (ANF) and porcine--human endothelin (ET-1) was investigated in the endothelium-denuded rat aortic ring preparation. ET-1 produced a sustained contraction of aortic rings with an ED50 of 3.6 +/- 0.49 x 10(-9) M. Within the concentration range of 10(-9) to 10(-7) M, both rat ANF 103-126 and rat ANF 99-126 when preincubated with tissues reduced the contractile efficacy of ET-1 especially at low concentrations resulting in a small but significant rightward shift of the dose--response curve to ET-1. In contrast, at a concentration of 10(-10) M, rANF 99-126 but not rANF 103-126 produced a significant leftward shift of the dose--response curve to ET-1 and an increase in the maximal developed tension for the dose--response curve to ET-1. For tissues incubated in the absence of extracellular calcium or in the presence of the calcium channel blocker nifedipine (5 x 10(-7) M), both ANF derivatives produced a dose-dependent decrease in the maximum contraction, but no change in potency to ET-1. Addition of either rANF 103-126 or rANF 99-126 to tissues maximally contracted with ET-1 resulted in relaxation, reaching a maximum of 70%. The ED50 values for relaxation were 2.7 +/- 0.51 x 10(-8) and 3.5 +/- 0.60 +/- 10(-8) M for rANF 103-126 and rANF 99-126, respectively. ET-1 did not interact with biologically responsive and clearance receptors for ANF.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of hepatic glycolysis and gluconeogenesis by atrial natriuretic peptide.

Recently we reported the presence of both the guanylyl cyclase-linked (116 kDa) and the ANF-C (66 kDa) atrial natriuretic peptide receptors in the rat liver. Since ANF 103-125 (atriopeptin II) stimulates cGMP production in livers and because cGMP has previously been shown to mimic the actions of cAMP in regulating hepatic carbohydrate metabolism, studies were performed to investigate the effects of atriopeptin II on hepatic glycolysis and gluconeogenesis. Additionally, employing analogs of atrial natriuretic hormone [des-(Q116, S117, G118, L119, G120) ANF 102-121 (C-ANF) and des-(C105,121) ANF 104-126 (analog I)] which bind only the ANF-C receptors, the role of the ANF-C receptors in the hepatic actions of atriopeptin II was evaluated. In perfused livers of fed rats atriopeptin II, but not C-ANF and analog I, inhibited hepatic glycolysis and stimulated glucose production. Moreover, analog I did not alter the ability of atriopeptin II to inhibit hepatic glycolysis. Atriopeptin II, but not C-ANF and analog I, also stimulated cGMP production in perfused rat livers. Furthermore, while atriopeptin II inhibited the activity ratio of pyruvate kinase by 30%, C-ANF did not alter hepatic pyruvate kinase activity. Finally, in rat hepatocytes, atriopeptin II stimulated the synthesis of [14C]glucose from [2-14C]pyruvate by 50% and this effect of atriopeptin II was mimicked by the exogenously supplied cGMP analog, 8-bromo cGMP. Thus atriopeptin II increases hepatic gluconeogenesis and inhibits glycolysis, in part by inhibiting pyruvate kinase activity, and the effects of atriopeptin II are mediated via activation of guanylyl cyclase-linked ANF receptors which elevate cGMP production.     

A linear analog of atrial natriuretic peptide (ANP) discriminates guanylate cyclase-coupled ANP receptors from non-coupled receptors

Atrial natriuretic peptide (ANP) contains a disulfide which is generally considered to be required for biological activity. A truncated linear ANP analog, des-Cys105,Cys121-ANP-(104-126) (referred to as analog I), that lacks the 2 cysteine residues of the parent peptide was synthesized. In competition binding studies using rabbit lung membranes, ANP-(103-126) and analog I displaced bound 125I-ANP-(103-126) from specific ANP binding sites 100 and 73%, respectively. The concentrations of ANP-(103-126) and analog I that produced 50% inhibition of radioligand binding to the membranes were 0.26 +/- 0.07 and 0.31 +/- 0.09 nM, respectively. Radioiodinated ANP-(103-126) and analog I were chemically cross-linked to binding sites on rabbit lung membranes, and the labeled membrane proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. 125I-Analog I specifically labeled a 65,000-dalton protein and a 135,000-dalton protein which, under reducing conditions, dissociated into 65,000-dalton subunits. In contrast, 125I-ANP-(103-126) labeled specifically a nonreducible 135,000-dalton protein, in addition to the 65,000-dalton species and the reducible 135,000-dalton species. ANP-(103-126) (100 nM) stimulated rabbit lung particulate guanylate cyclase activity, whereas analog I, at the same concentration, had no effect on cyclic GMP production and did not antagonize the effect of ANP-(103-126). From these observations, we conclude that analog I is a selective ligand which binds to approximately 73% of the total ANP binding sites present in rabbit lung membranes. Unlike ANP-(103-126), analog I does not bind to the remaining 27% of the binding sites and does not activate guanylate cyclase. Binding to the cyclase-linked ANP receptor correlates with the specific labeling by 125I-ANP-(103-126) of the nonreducible 135,000-dalton membrane protein.     

Nitric oxide-generating vasodilators inhibit mitogenesis and proliferation of BALB/C 3T3 fibroblasts by a cyclic GMP-independent mechanism.

The purpose of this study was to investigate the effects of nitric oxide-generating vasodilators and 8-bromo-cGMP on serum-induced mitogenesis in BALB/c 3T3 fibroblasts that lack soluble guanylate cyclase activity. Two such vasodilators, S-nitroso-N-acetylpenicillamine and isosorbide dinitrate, decreased the incorporation of (3H)thymidine in these cells dose-dependently whereas 8-bromo-cGMP was ineffective at concentrations of up to 10 mM. Moreover, S-nitroso-N-acetylpenicillamine also inhibited cell proliferation, consistent with the data on (3H)thymidine incorporation. S-nitroso-N-acetylpenicillamine had no effect on cGMP accumulation, confirming previous studies that these cells lack soluble guanylate cyclase activity. Hemoglobin and FeSO4/ascorbate, agents that inhibit the actions of nitric oxide, both decreased S-nitroso-N-acetylpenicillamine-induced antimitogenesis, supporting the view that this effect was related to the generation of nitric oxide. The antimitogenic activity of S-nitroso-N-acetylpenicillamine was unlikely to be the expression of nitric oxide-induced degradation of serum mitogens, as indicated by the decrease of the antimitogenic activity on prolonged preincubation of SNAP in serum-containing medium. We conclude that nitric oxide-generating vasodilators inhibit serum-induced mitogenesis and cell proliferation in BALB/c 3T3 fibroblasts by a cGMP-independent mechanism.     

Atrial peptide inactivation by rabbit-kidney brush-border membranes

Atriopeptin (AP) 24, containing amino acids Ser103-Tyr126 of the carboxy-terminal portion of the atrial natriuretic peptide prohormone, was degraded rapidly by rabbit kidney brush border membranes. The rate of degradation of AP24 measured by the loss of vasorelaxant activity followed a similar time course to the decrease in peptide peak area measured by high-performance liquid chromatography. Inactivation of AP24 produced peptide fragments which were separated by HPLC. The major products were purified individually and their peptide sequences determined. Results indicate that AP24 was proteolytically cleaved at three peptide bonds: Ser103-Ser104, Cys105-Phe106 and Ser123-Phe124. des-Ser103-AP24 had similar vasorelaxant activity to AP24, while AP24 cleaved at Cys105-Phe106 was inactive. Regarding the proteolytic cleavage at Ser123-Phe124, there was an accumulation of the C-terminal tripeptide, Phe-Arg-Tyr, only at the later time points of the incubation. Degradation experiments were repeated with an amino- and carboxy-terminal protected peptide, acetyl-AP24-amide. Peptide sequence analysis of the major degradation products of this peptide revealed that the critical peptide bond cleaved was Cys105-Phe106. We conclude that the Cys-Phe peptide bond renders atrial peptides highly susceptible to proteolysis by renal brush border membranes, resulting in inactivation.     

Atrial natriuretic peptides cleaved by endopeptidase are inactive in conscious spontaneously hypertensive rats

The dose-related natriuretic and depressor responses to atrial natriuretic peptides (ANP) 99-126, 103-126 and 103-123 were determined in unanesthetized spontaneously hypertensive rats (SHR) and were compared to the activities of their Cys105-Phe106 ring-opened metabolites. These metabolites were previously identified as the major initial products formed by incubation of the intact peptides with neutral endopeptidase (NEP). The areas over the curves (AOC) of the depressor responses to the intact peptides were dose-related and, at 30 nmole/kg, iv were greatest for ANP 99-126 and 103-126 (833 +/- 241 and 1157 +/- 221 mm Hg x min). Thirty nmole/kg of ANP 103-123, a possible product of NEP cleavage of ANP 103-126, produced a lesser AOC (442 +/- 152 mm Hg x min) than did either of the longer peptides. The AOC responses to 100 nmole/kg of the ring-opened metabolites of ANP 99-126, 103-126 and 103-123 (105 +/- 80, 153 +/- 43 and 148 +/- 64 mm Hg x min) were not significantly different from the effect of vehicle treatment (84 +/- 23 mm Hg x min). Although the natriuretic responses to increasing doses of the intact peptides did not occur in a linear fashion, sodium excretion was maximally elevated by 24 +/- 4, 16 +/- 3 and 10 +/- 3 microEq/kg/min by 3 nmole/kg of ANP 99-126, 30 nmole/kg of ANP 103-126 and 10 nmole/kg of ANP 103-123, respectively. In contrast, the natriuretic responses to 100 nmole/kg of the ring-opened metabolites of ANP 99-126, 103-126 and 103-123 (1 +/- 0, 5 +/- 2 and 2 +/- 1 microEq/kg/min, respectively) were not significantly different from the response to vehicle treatment (3 +/- 1 microEq/kg/min). In conclusion, three ring-opened products of NEP cleavage of ANP 99-126, 103-126 and 103-123 were inactive in conscious SHR.     

Competitive peptide antagonists of ANF-induced cyclic guanosine monophosphate production

Atrial natriuretic factor (isoleucine ANF 101-126), cleaved ANF (isoleucine ANF 101-105/106-126) and des (Gln 18, Ser 19, Gly 20, Leu 21, Gly 22) ANF 4-23-NH2 (C-ANF 4-23) stimulated cyclic guanosine monophosphate production (cGMP) by rat aortic vascular smooth muscle cells (VSMC) in culture. Cleaved ANF and ANF C4-23 also antagonised or diminished the response to ANF 101-126. Agonist and antagonist actions of both peptides were dose-related. In contrast, prepro ANF (104-123), an ANF precursor fragment, exhibited no agonist or antagonist effect on cGMP production.     

Atrial natriuretic peptide, ANP(99-126), receptors in rat thymocytes and spleen cells

A single class of saturable, specific binding sites for the circulating form of atrial natriuretic peptides, ANP(99-126), was identified in rat thymus and spleen and in isolated thymocytes and spleen cells using quantitative autoradiographic techniques. In the thymus, the relative potency of ANP analogs to inhibit [125I] ANP(99-126) binding was ANP(99-126) = ANP(103-126) greater than ANP(111-126) greater than ANP(103-125). ANP(103-123) could not displace [125I]ANP(99-126) binding. Addition of ANP(99-126) stimulated the formation of cyclic GMP in isolated thymocytes and spleen cells in a dose-dependent manner. Our results indicate that immune cells have specific ANP receptors which could be coupled to guanylate cyclase activation and may play a role in the regulation of the immune response.     

Atrial granules contain an amino-terminal processing enzyme of atrial natriuretic factor

At least three enzymes have been identified in atrial tissue homogenates that are capable of processing pro-atrial natriuretic factor to active atrial peptides. The atrial peptides possess potent natriuretic, diuretic, vasorelaxant, and hemodynamic properties, and their existence has implicated the mammalian heart as an endocrine organ. We have purified and characterized a serine proteinase (Mr approximately equal to 70,000) associated with atrial granules that preferentially hydrolyzes the Arg-Ser bond in the synthetic substrates Gly-Pro-Arg-Ser-Leu-Arg, benzoyl-Gly-Pro-Arg-Ser-Leu-Arg, and benzoyl-Gly-Pro-Arg-Ser-Leu-Arg-Arg-2-naphthylamide, the Arg-2-naphthylamide bond in the substrate benzoyl-Gly-Pro-Arg-2-naphthylamide, and the Arg-Ser bond in a 31-residue substrate (Gly96-Tyr126 peptide) corresponding to residues Arg98-Ser99 in pro-atrial natriuretic factor. The Gly96-Tyr126 peptide contains the putative processing site in pro-atrial natriuretic factor and the sequence for the bioactive peptides. Our results indicate that the minimum processing site sequence is -Gly-Pro-Arg-Ser-Leu-Arg-Arg- and that the Ser99-Tyr126 natriuretic peptide is the predominant hydrolytic product. After prolonged incubation or at high enzyme concentrations, the Ser103-Tyr126 natriuretic peptide may also be formed. The Ser103-Arg125 natriuretic peptide was only a very minor product. The doublet of basic amino acids is not the primary processing site in pro-atrial natriuretic factor, but their presence may influence cleavage at the single Arg residue "upstream." Our findings are consistent with the idea that the pro-protein and the processing enzymes are packaged into the secretory granule and in response to the proper stimulus, the pro-protein is processed to the active peptides, probably during the process of secretion. The processing pathway of pro-atrial natriuretic factor is discussed.     

Ovine atrial natriuretic factor: sequence of circulating forms and metabolism in plasma.

The sequence of ovine ANF is not known, yet sheep have been used extensively for ANF studies. We sequenced the circulating form of ovine ANF from coronary sinus plasma of sheep in paced heart failure. The main circulating form was identical to human ANF(99-126). Small amounts of ANF identical to human ANF(103-126) and ANF(101-126) peptides were also found. Incubation of labeled ANF in ovine serum suggested ANF(103-126) could be a degradation product of ANF(99-126). The endopeptidase-24.11 degradation product ANF(99-105/106-126) was not found in ovine plasma, in contrast to human plasma where it was a minor component. These results show that while the main circulating forms are similar in sheep and humans, there are differences in the minor peptides.     

Endopeptidase-24.11 in human plasma degrades atrial natriuretic factor (ANF) to ANF(99-105/106-126)

We previously demonstrated the presence of ANF(99-126), and ANF(99-126) cleaved between Cys105 and Phe106 (cleaved ANF), in human coronary sinus plasma. We now report that cleaved ANF is formed when synthetic ANF(99-126) is added to human plasma. When synthetic ANF(99-126) was incubated in heparinized human plasma, HPLC analysis showed two degradation products. The main product was shown by amino acid and sequence analysis to be cleaved ANF. Degradation of ANF was inhibited by EDTA and phosphoramidon. These findings are consistent with the action of endopeptidase EC 3.4.24.11, which may play an important part in the biological inactivation of ANF.     

Phosphorylation of high- and low-molecular-mass atrial natriuretic peptide analogs by cyclic AMP-dependent protein kinase

Synthetic high- and low-molecular-mass atrial peptides were phosphorylated in vitro by cyclic AMP-dependent protein kinase and [32P]ATP. From a series of atrial peptide analogs, it was deduced that the amino acid sequence, Arg101-Ser104 of atriopeptin was required for optimal phosphorylation. Phosphorylated AP(99-126) was less potent than the parent atriopeptin in vasorelaxant activity and receptor-binding properties. These results indicate that the presence of a phosphate group at the N-terminus of AP(99-126) decreases the interaction of the peptide with its receptor and, as a consequence, decreases bioactivity. These observations are in contrast to those of Rittenhouse et al. [(1986) J. Biol. Chem. 261, 7607-7610] who reported that phosphorylation of AP(101-126) enhanced the stimulation of Na/K/Cl cotransport in cultured vascular smooth muscle cells.     

A synthetic linear decapeptide binds to the atrial natriuretic peptide receptors and demonstrates cyclase activation and vasorelaxant activity

A linear decapeptide, [cyclohexylalanine 106]ANP-(105-114)NH2 (1), where ANP is atrial natriuretic peptide, was prepared by solid phase synthesis and purified by reverse-phase liquid chromatography. This novel peptide was found to bind to ANP receptors in rabbit lung membranes, to stimulate cGMP production in various tissues, and to fully relax precontracted rabbit aorta in a dose-dependent fashion. The potency of 1 in the various in vitro assays varies between one-twentieth and one-eightieth of the potency of the reference peptide, the 24-mer rat ANP-(103-126). The linear decapeptide 1, which encompasses amino acid residues from the rat ANP sequence (105-114), features a cyclohexylalanine residue instead of the phenylalanine 106 residue in the hormone sequence, a free sulfhydryl function at the N-terminal cysteine 105, and a carboxamide C terminus. Its disulfide dimer 6 was active in the rabbit aorta assay while the S-methyl cysteine 7 analogue was not active in the same assay at similar concentrations. The decapeptide 1 is of particular significance because it is the shortest analogue reported to date endowed with agonistic activity at the guanylate cyclase-coupled ANP receptor. In particular, it is interesting to compare its structure to the structures of other short linear analogues of ANP which are totally devoid of the ability to stimulate particulate guanylate cyclase activity.     

Covalently cyclized agonist and antagonist analogues of bombesin and related peptides.

During a search for possible cyclization points in shortened, potent bombesin agonists and antagonists, it was found that the joining of amino acid residues in positions 6 and 14 by various means resulted in retention of significant binding affinity for rat pancreatic acini and murine Swiss 3T3 cells. In one series of analogues, Cys residues in these positions were used for bridging via a disulfide bond. (D)-C-Q-W-A-V-G-H-L-C-NH2 retained significant binding affinity for rat pancreatic acini cells and was a full amylase releasing agonist (EC50 187 nM). Potency was markedly increased by substituting D-Ala for Gly (EC50 67 nM compared to 10 nM for its linear counterpart) and was decreased by substituting L-Cys for D-Cys in this analogue (EC50 214 nM), thus strongly suggesting stabilization of peptide folding by the D residues. Elimination of the COOH-terminal amino acid produces competitive antagonists in the linear analogues; however, (D)-C-Q-W-A-V-G-H-C-NH2 was devoid of activity. Likewise, cyclization to position 13 with the 14 amino acids intact to give (D)-C-Q-W-A-V-G-H-C-L-NH2 resulted in an almost inactive peptide. On the other hand, as in the linear series, the reduced peptide bond analogue, (D)-C-Q-W-A-V-(D)-A-H-L-psi (CH2NH)-C-NH2, was a receptor antagonist (IC50 5.7 mM), albeit much weaker than the corresponding linear analogues, but with no residual agonist activity. Direct head-to-tail cyclization was also tried. Both cyclo[(D)-F-Q-W-A-V-G-H-L-L] (EC50 346 nM) and the shorter cyclo [Q-W-A-V-G-H-L-L] (EC50 1236 nM) were full agonists. Elimination of the COOH-terminal residue in cyclo[(D)-p-Cl-F-Q-W-A-V-(D)-A-H-L] produced an agonist (EC50 716 nM) rather than an antagonist. These results provide support for the proposal that both bombesin agonists and antagonists adopt a folded conformation at their receptor(s). Furthermore, the retention of appreciable potencies using several cyclization strategies and chain lengths suggests that further optimization of these structures both in terms of potency and ring size is possible. Since these peptides have increased conformational restriction, they should begin to serve as useful substrates for NMR and molecular modeling studies aimed at comparing the obviously subtle differences between agonist and antagonist structures.     

Lack of association of epidermal growth factor-, insulin-, and serum-induced mitogenesis with stimulation of phosphoinositide degradation in BALB/c 3T3 fibroblasts

The hypothesis that inositol phospholipid degradation is a step in the mechanism by which epidermal growth factor (EGF) stimulates mitogenesis in confluent monolayers of quiescent BALB/c 3T3 fibroblasts was tested. The maximum mitogenic response (a nearly 30-fold increase in incorporation of [3H]thymidine) occurred at 1 ng/ml EGF (0.16 nM). This degree of stimulation corresponded to 60% of that elicited by 10% serum. To determine whether EGF stimulated formation of inositol phosphates via degradation of polyphosphoinositides, the intracellular levels of [3H] inositol phosphates and [3H]phosphoinositides were determined after EGF addition to BALB/c 3T3 fibroblasts prelabeled with [3H]inositol. These experiments were performed under conditions designed to mimic exactly those conditions used to study mitogenesis. The results demonstrated that 10% serum or 10 ng/ml of platelet-derived growth factor, but not as much as 50 ng/ml EGF or 10 micrograms/ml insulin, increased the levels of inositol phosphates via degradation of phosphoinositides in the presence of 10 mM Li+. The serum-induced effects occurred in 30 s, the earliest time investigated. Phorbol dibutyrate (100 nM), alone or in conjunction with EGF (10 ng/ml), failed to stimulate inositol phospholipid degradation. However, phorbol dibutyrate inhibited the serum-induced stimulation. Finally, fetal bovine serum dialyzed so as to retain peptide mitogens lost almost 70% of the capacity to stimulate degradation of inositol phospholipids while remaining as mitogenic as the control serum. Thus, stimulation of inositol phospholipid degradation is an unlikely component in the mechanism by which EGF and probably insulin and serum stimulate mitogenesis in BALB/c 3T3 fibroblasts.