Binding affinities and activation of Asp712Ala and Cys100Ser mutated kinin B1 receptor forms suggest a bimodal scheme for the molecule of bound-DABK.

Mutant forms of kinin B(1) receptor (B(1)R) and analogs of the full agonist des-Arg(9)-bradykinin (DABK) were investigated aiming to verify the importance of selected receptor residues and of each agonist-peptide residue in the specific binding and activation. Linked by a specific disulfide bond (Cys(100)-Cys(650)), the N-terminal (N(t)) and the EC3 loop C-terminal (C(t)) segments of angiotensin II (AngII) receptor 1 (AT(1)R) have been identified to form an extracellular site for binding the agonist N(t) segment (Asp(1) and Arg(2) residues). Asp(712) residue at the receptor EC3 loop binds the peptide Arg(2) residue. By homology, a similar site might be considered for DABK binding to B(1)R since this receptor contains the same structural elements for composing the site in AT(1)R, namely the disulfide bond and the EC3 loop Asp(712) residue. DABK, Ala(n)-DABK analogs (n=Ala(1)-, Ala(2)-, Ala(3)-, Ala(4)-, Ala(5)-, Ala(6)-, Ala(7)-, Ala(8)-DABK), and other analogs were selected to binding wild-type, Asp712Ala and Cys100Ser mutated B(1)R receptors. The results obtained suggested that the same bimodal scheme adopted for AngII-AT(1)R system may be applied to DABK binding to B(1)R. The most crucial similarity in the two cases is that the N(t) segments of peptides equally bind to the homologous Asp(712) residue of both AT(1)R and B(1)R extracellular sites. Confirming this preliminary supposition, mutation of residues located at the B(1)R extracellular site as EC3 loop Asp(712) and Cys(100) caused the same modifications in biological assays observed in AT(1)R submitted to homologous mutations, such as significant weakening of agonist binding and reduction of post-receptor-activation processes. These findings provided enough support for defining a site that determines the specific binding of DABK to B(1)R receptors.

Functional expression of kinin B1 and B2 receptors in mouse abdominal aorta

Previous studies have shown that the vascular reactivity of the mouse aorta differs substantially from that of the rat aorta in response to several agonists such as angiotensin II, endothelin-1 and isoproterenol. However, no information is available about the agonists bradykinin (BK) and DesArg9BK (DBK). Our aim was to determine the potential expression of kinin B1 and B2 receptors in the abdominal mouse aorta isolated from C57BL/6 mice. Contraction and relaxation responses to BK and DBK were investigated using isometric recordings. The kinins were unable to induce relaxation but concentration-contraction response curves were obtained by applying increasing concentrations of the agonists BK and DBK. These effects were blocked by the antagonists Icatibant and R-715, respectively. The potency (pD2) calculated from the curves was 7.0 ± 0.1 for BK and 7.3 ± 0.2 for DBK. The efficacy was 51 ± 2 percent for BK and 30 ± 1 percent for DBK when compared to 1 æM norepinephrine. The concentration-dependent responses of BK and DBK were markedly inhibited by the arachidonic acid inhibitor indomethacin (1 æM), suggesting a mediation by the cyclooxygenase pathway. These contractile responses were not potentiated in the presence of the NOS inhibitor L-NAME (1 mM) or endothelium-denuded aorta, indicating that the NO pathway is not involved. We conclude that the mouse aorta constitutively contains B1 and B2 subtypes of kinin receptors and that stimulation with BK and DBK induces contractile effect mediated by endothelium-independent vasoconstrictor prostanoids.

Functional expression of kinin B1 and B2 receptors in mouse abdominal aorta.

Previous studies have shown that the vascular reactivity of the mouse aorta differs substantially from that of the rat aorta in response to several agonists such as angiotensin II, endothelin-1 and isoproterenol. However, no information is available about the agonists bradykinin (BK) and DesArg(9)BK (DBK). Our aim was to determine the potential expression of kinin B(1) and B(2) receptors in the abdominal mouse aorta isolated from C57BL/6 mice. Contraction and relaxation responses to BK and DBK were investigated using isometric recordings. The kinins were unable to induce relaxation but concentration-contraction response curves were obtained by applying increasing concentrations of the agonists BK and DBK. These effects were blocked by the antagonists Icatibant and R-715, respectively. The potency (pD(2)) calculated from the curves was 7.0 +/- 0.1 for BK and 7.3 +/- 0.2 for DBK. The efficacy was 51 +/- 2% for BK and 30 +/- 1% for DBK when compared to 1 microM norepinephrine. The concentration-dependent responses of BK and DBK were markedly inhibited by the arachidonic acid inhibitor indomethacin (1 microM), suggesting a mediation by the cyclooxygenase pathway. These contractile responses were not potentiated in the presence of the NOS inhibitor L-NAME (1 mM) or endothelium-denuded aorta, indicating that the NO pathway is not involved. We conclude that the mouse aorta constitutively contains B(1) and B(2) subtypes of kinin receptors and that stimulation with BK and DBK induces contractile effect mediated by endothelium-independent vasoconstrictor prostanoids.

Tachyphylactic properties of angiotensin II analogs with bulky and hydrophobic substituents at the N-terminus.

Tachyphylaxis, defined as the acute loss of response of some smooth muscles upon repeated stimulations with angiotensin II (Ang II), has been shown to be dependent mainly on the N-terminal region of the ligand. To further study the structural requirements for the induction of tachyphylaxis we have synthesized Ang II analogs containing the bulky and very lipophilic substituents 9-fluorenylmethyloxycarbonyl (Fmoc) and 9-fluorenylmethyl ester (OFm) at the alpha-amino (Nalpha-Fmoc-Ang II) or the beta-carboxyl ([Asp(OFm)1]-Ang II) groups of the Asp1 residue, respectively. In binding assays with Chinese hamster ovary cells transfected with the AT1 Ang II receptor, Nalpha-Fmoc-Ang II bound with high affinity, whereas [Asp(OFm)1]-Ang II showed lower affinity. In biological assays, these two analogs were full agonists and showed 30 and 3%, respectively, of the Ang II potency in contracting the guinea-pig ileum smooth muscle. The two analogs induced tachyphylaxis, in spite of the lack of a free amino group in Nalpha-Fmoc-Ang II. Thus, analogs with Fmoc- or OFm-type groups coupled to the Asp1 residue, whether at the amino or carboxyl functions, induce tachyphylaxis through an unreported mechanism. Based in these findings and those available from the literature, an alternate molecular interaction mode between Ang II N-terminal portion and the AT1 receptor is proposed to explain the tachyphylactic phenomenon.

Pharmacological characterization of RMP-7, a novel bradykinin agonist in smooth muscle.

RMP-7 is a bradykinin (BK) agonist designed to be resistant to kininases such as angiotensin-converting enzyme (ACE). Pharmacological assays were performed with RMP-7 in isolated guinea-pig ileum and rat mesenteric artery. RMP-7 induced contractile responses in the guinea-pig ileum, where the apparent affinity of the peptide (pD2) was significantly lower than that determined for BK (7.3 +/- 0.07 vs. 8.3 +/- 0.05, respectively). HOE-140 blocked this effect indicating that B2 receptor was involved. Captopril (1 microM) had no potentiating effect on RMP-7 but increased pD2 value determined for BK (8.8 +/- 0.1), confirming a high resistance of RMP-7 to the ACE. In rat mesenteric artery, RMP-7 induced endothelium-dependent relaxation (7.8 +/- 0.4), with a higher affinity than that of BK which induced vasodilatation only in the presence of 1 microM captopril (6.9 +/- 0.36). Nevertheless, the maximum effect induced by RMP-7 was lower than that of BK in contrast to that observed in guinea-pig ileum although B2 receptor was involved in both cases. We concluded that: RMP-7 is greatly resistant to the ACE and that the receptor sites activated by RMP-7 and BK show important differences in vascular and non-vascular preparations probably due to the different sensitivity of the B2 receptor to RMP-7.

Insertion of an electronegative sulfur atom in the side chain of position 5 of angiotensin II: changes in the tachyphylactic properties of the peptide.

Angiotensin II (AII) analogs bearing n-Leu, Met or S-substituted groups for cysteine at position 5 were studied regarding their agonistic and tachyphylactic properties. It was shown that these analogs lowered the relative affinity towards the AT1 receptor as determined by contractile responses, which could be due to the removal of the beta-branching residue at position 5. Insertion of a sulfur atom in a different position away from the attached backbone carbon atom presented no significant difference in EC50 values for these analogs. Interestingly, the S-bearing analogs at position 5 were full agonists but the tachyphylactic property was lost, in contrast to [n-Leu5]AII, which still induced reduction of the contractile responses. Nevertheless after replacing the Asp with Sar in position 1 (Sar1) tachyphylaxis was again established. It is concluded that the insertion of Met or an S-substituted cysteine into the side chain at position 5 of AII may promote interactions with its receptor due to the slight electronegative character of the sulfur atom and changes in the restricted conformational freedom of the Ile5 residue in the AII molecule. This was overcome by Sar1, probably through interactions due to its fully protonated N-terminal amino group and favoring the conformation responsible for the tachyphylaxis phenomenon.

Different pathways for Ca2+ mobilization by angiotensin II and carbachol in the circular muscle of the guinea-pig ileum.

Ca2+ pathways activated by angiotensin II and carbachol were evaluated in the circular muscle of the guinea-pig ileum by recording mechanical and electrical activities. Transient contractions induced by angiotensin II were greatly reduced by Ca2+ removal from the medium whereas carbachol-induced responses were not significantly altered. Nifedipine had no effect on the responses to both agonists. A high concentration of tetrodotoxin (0.1 microM) inhibited angiotensin II-induced contractile responses without affecting the depolarization, whereas 1 mM Ni2+ inhibited the mechanical and electrical effects. Neither tetrodotoxin nor Ni2+ affected carbachol-induced effects. These results indicate that angiotensin II-induced phasic contractions depend on extracellular Ca2+ but not on voltage-dependent L-type Ca2+ channels. It is suggested that angiotensin II activates Ni2+-sensitive Na+ and non-specific cationic channels, whereas the responses to carbachol are dependent on receptor-activated Ca2+ release. Furthermore the different response of the longitudinal and circular muscles to the inhibitory effects of tetrodotoxin and Ni2+ on the angiotensin II- and carbachol-induced contractions indicates that these agonists exert their own myogenic effects on each layer and are able to trigger different Ca2+ mobilization pathways.

Residues Val254, His256, and Phe259 of the angiotensin II AT1 receptor are not involved in ligand binding but participate in signal transduction.

The role of the external third of helix VI of the angiotensin II (AII) AT1 receptor for the interaction with its ligand and for the subsequent signal transduction was investigated by individually replacing residues 252-256 by Ala, and residues 259 or 261 by Tyr, and permanently transfecting the resulting mutants to Chinese hamster ovary (CHO) cells. Binding experiments showed no great changes in affinity of any of the mutants for AII, [Sar1]-AII, or [Sar1, Leu8]-AII, but the affinity for the nonpeptide antagonist DuP753 was significantly decreased. The inositol phosphate response to AII was remarkably decreased in mutants V254A, H256A, and F259Y. These results indicate that AT1 residues Val254, His256, and Phe259 are not involved in ligand binding but participate in signal transduction. Based in these results and in others from the literature, it is suggested that, in addition to the His256 imidazole ring, the Phe259 aromatic ring interacts with the AII's Phe8, thus contributing to the signal-triggering mechanism.

Angiotensin II tachyphylaxis in the guinea pig ileum and its prevention: a pharmacological and biochemical study.

Angiotensin II (AII) tachyphylaxis occurs in the guinea pig ileum, but is not induced by analogs lacking the N-terminal amino group or the Arg2 guanidino group. Both AII and Lys2AII increased cell inositol trisphoshate content in cultured intestinal smooth muscle cells. Protein kinase C inhibition by staurosporine or downregulation by prolonged incubation with phorbol reverted tachyphylaxis of the inositol trisphoshate response, but not that of the Na+ uptake response, indicating that the uncoupling of the phosphoinositide signal system by protein kinase C did not involve all processes distal to receptor activation. Tachyphylaxis of the Na+ uptake response was prevented when receptor internalization was blocked by reduction of the temperature (4 degrees C) or by pretreatment of the cells with phenylarsine oxide. Acid washings, which prevented tachyphylaxis of the 24Na+ influx response, also prevented tachyphylaxis of the contractile response of the guinea pig ileum to AII. Although these findings suggest that sequestration or internalization of the AII receptor might be involved in AII tachyphylaxis, binding of [125I]AII and of [125I]Lys2AII to the cells was equally unaffected by repeated administrations of the peptides. The results suggest that conformational change of the AII-receptor complex within the plasma membrane, but not internalization, is the most important factor responsible for tachyphylaxis.

Role of Na+ and protein kinase C in angiotensin desensitization and tachyphylaxis in the guinea-pig ileum.

Simultaneous recordings of the tension and intracellular Ca2+ concentration of guinea-pig ileum longitudinal smooth muscle strips, as well as 24Na+ and 45Ca2+ influx measurements in cultured myocytes from the same tissue, were used to investigate the mechanisms underlying angiotensin-induced desensitization and tachyphylaxis. Angiotensin II and [2-lysine]-angiotensin II (Lys2All), incubated for prolonged periods (10 min) with muscle strips, induced fading of the contractile response (desensitization) and reappearance of the intracellular Ca2+ concentration oscillations, which were inhibited during the initial increase in cytosolic Ca2+. The desensitization was paralleled, in cultured myocytes, by inhibition of the 45Ca2+ but not of the 24Na+ influxes which were initially stimulated by the peptides. On the other hand, repeated administrations of angiotensin II (but not of Lys2All) caused gradual reduction of the contractile response and of the 24Na+ influx stimulation evoked by the agonist (tachyphylaxis). Treatment with phorbol 12-13 dibutyrate accelerated the desensitization induced by both angiotensin II and by Lys2All and aggravated the tachyphylaxis to angiotensin II. The results support the hypothesis that activation of protein kinase C is responsible for the desensitization and that tachyphylaxis is due to the slow dissociation of angiotensin II from a postulated Na(+)-dependent regulatory site on the receptor.

Angiotensin II desensitization and Ca++ and Na+ fluxes in cultured intestinal smooth muscle cells.

The effects of angiotensin II (ANG) on Na+ and Ca++ fluxes in cultured intestinal smooth muscle cells from the guinea pig ileum were studied and correlated with the contraction and desensitization observed in whole muscles. The effects of ANG were compared with those of acetylcholine (ACh), an agonist that acts at muscarinic receptors in the intestinal smooth muscle and which does not induce desensitization. Both ANG and ACh stimulated 24Na+ influx upon addition to the cells, and this stimulation persisted for at least 30 min. Both agonists also stimulated 45Ca++ uptake but ANG's effect was transient, whereas that of ACh was persistent. Short-term (30 min) treatment with PMA (phorbol-12-myristate-13-acetate) caused a fade of the tonic response of the whole muscle to ANG, and also blocked this hormone's stimulating effect on 45Ca++, but not on 24Na+ influx. Long-term (7 hr) treatment with PMA, which suppresses protein kinase C activity, restored ANG's ability to stimulate 45Ca++ influx. The stimulating effects of ACh on 24Na+ and 45Ca++ influxes were not affected by short- or long-term treatment of the cells with PMA. Our results suggest that ANG desensitization involves protein kinase C inhibition of a step in the stimulus-response chain that is subsequent to phospholipase C-activation.

Angiotensin II desensitization and Ca2+ and Na+ fluxes in vascular smooth muscle cells.

The role of ion fluxes in angiotensin II (AII) desensitization (tachyphylaxis) was investigated by studying Na+ and Ca2+ translocation in cultured vascular smooth muscle cells from the rat aorta. The effects of AII were compared to those of [1-sarcosine]-AII (Sar1-AII), an analogue which also induces tachyphylaxis, and [2-lysine]-AII (Lys2-AII), an analogue that does not show this property. Maximally effective concentrations of the three peptides induced a rapid and transient increase in 45Ca2+ efflux, a rapid and sustained decrease in total cell Ca2+ and an increased Na+ permeability. Repeated treatments, at short intervals, with either of the three peptides abolished the effect on Ca2+ efflux, and this desensitization was slowly reversible. A 30-min rest period was sufficient for full recovery of the response of cells that were desensitized by Lys2-AII, whereas the recovery from AII or Sar1-AII-desensitization was still not complete after 60 min. Our results suggest that the difference in the behaviour of the "tachyphylactic" AII and Sar1-AII and the "non-tachyphylactic" Lys2-AII lays not in the production of different signals upon binding to the receptor, but in a difference in the hormone-receptor interaction itself.

Selectivity of bradykinin analogues for receptors mediating contraction and relaxation of the rat duodenum.

1. Bradykinin produces a biphasic response in the rat duodenum that consists of a relaxation (pD2 = 8.44) followed by a contraction (pD2 = 6.91). 2. The B1 agonist des-Arg9-bradykinin produced a contraction (pD2 = 7.16) but no relaxation. Des-Arg9-[Leu8]-bradykinin, which is a B1 antagonist in other systems produced contraction (pD2 = 7.65) in the rat duodenum. 3. Four bradykinin analogues that are preferential B2 agonists in other tissues had a biphasic effect with pD2 values in the range 7.22-8.68 for relaxation and 6.26-6.91 for contraction. 4. [Thi5,8,D-Phe7]-bradykinin, which is a B2 antagonist in most other systems produced relaxation in the rat duodenum, with a pD2 of 7.49. 5. It is concluded that the contractile component of the response to bradykinin in rat duodenum may be mediated by a subtype of the B1 receptor and the relaxant component by a receptor of the B2 subtype.

Changes in residues 1 and 4 of angiotensin II affect differently its agonist and tachyphylactic properties.

Two series of angiotensin II analogues with modifications at positions 1 or 4 of the peptide chain were studied with respect to their tachyphylactic properties and to the kinetics of relaxation of the guinea-pig ileum after a contractile response to maximally effective concentrations. Tachyphylaxis was measured by the decrease in response amplitude after three successive treatments ("tachyphylactic index") and the relaxation rate was evaluated by the time taken for the tonus to reach half of its value at the moment of agonist washout ("half relaxation time"). A correlation between tachyphylactic index and half relaxation time was found for the series of position 1 analogues, but not for the position 4 analogues. For the two series, the half relaxation times of the tachyphylactic analogues decreased from the first to the third of a series of successive treatments. Bulky substituents at position 1, which did not greatly affect the agonist activity, suppressed the tachyphylactic property. The results provide evidence that the agonist and tachyphylactic properties of angiotensin II are due to its interaction, respectively, with an agonist site and a "tachyphylaxis" site on the receptor and that the structural requirements for binding to the two sites are different.

Evidence for a regulatory site in the angiotensin II receptor of smooth muscle.

The homologous desensitization induced by angiotensin II analogues in the guinea-pig isolated ileum was studied. Desensitization assessed by the loss of response on repeated treatment showed [Sar1]angiotensin II to be a strong desensitizer whereas no desensitization to [Lys2]angiotensin II was detected. However, prolonged treatment with either analogue desensitized the tissue, indicating that [Lys2]angiotensin II-induced desensitization was reversed faster. A correlation was found between the degree of desensitization caused by repeated treatment and the time for half-relaxation after washout of the first treatment, but the relaxation after washout became faster in the desensitized state. In experiments designed to study competition between the agonistic and desensitizing properties of angiotensin II analogues, high concentrations of [Lys2]angiotensin II blocked the agonistic but not the desensitizing effect of lower concentrations of [Sar1]angiotensin II. It is concluded that desensitization is due to the interaction of angiotensin II with a regulatory site on the receptor.

Role of sodium ions in angiotensin tachyphylaxis in the guinea-pig ileum and taenia coli.

We have examined the responsiveness of the guinea-pig ileum and taenia coli to angiotensin (ANG) analogues that were previously shown to be either able ([1-sarcosine]-ANG, Sar1-ANG) or unable ([2-lysine]-ANG, Lys2-ANG) to induce tachyphylaxis in the ileum. The taenia coli, in which tachyphylaxis had not been previously shown to occur, was strongly tachyphylactic to Sar1-ANG, but not to Lys2-ANG. The contractile responses of the ileum, as well as the contractile and electrical (sucrose-gap) events in the taenia coli, in response to the two ANG analogues, were used to investigate the tachyphylactic phenomenon and the role of Na+ in the manifestation. Relaxation of the ileum and repolarizations of the taenia coli were faster after treatment with Lys2-ANG than after Sar1-ANG. In the tachyphylactic state, relaxation and repolarization after Sar1-ANG became as fast as after Lys2-ANG. In "low-Na+" (80 mmol/l) medium, as well as in ouabain-treated preparations, the responses of the ileum to ANG analogues were similar to those of tissues in the tachyphylactic state. Addition of Ca2+ to taenia coli preparations previously treated with the two ANG analogues in Ca2+-free medium, caused contractile and electrical responses only in the case of Sar1-ANG. It is proposed that ANG tachyphylaxis is due to changes at the level of the receptor causing increased Na+ permeability which leads to a decreased Na+ gradient across the cell membrane.

Amiloride inhibition of guinea pig contractile responses to acetylcholine.

1. Amiloride inhibited the tonic component of the responses of the isolated guinea pig ileum to high (1 microM, which is above ED50), but not to low (44 nM) concentrations of acetylcholine. 2. The inhibition was concentration-dependent in the range 0.1 microM-10 microM and was attenuated in low-Na+ or high-Ca2+ media. 3. Amiloride (10 microM) inhibited the increase of 45Ca2+ uptake induced by 1 microM acetylcholine in the longitudinal muscle of the guinea pig ileum. 4. These results suggest that amiloride inhibits agonist-induced Na+ influx and indirectly Ca2+ influx through the Na+/Ca2+ exchange mechanism.

Membrane potential and reactivity to potassium of duodenal smooth muscle from spontaneously hypertensive rats.

Na/K-ATPase from the duodenum of spontaneously hypertensive rats (SHR) is inhibited compared to that of the Wistar-Kyoto (WKY) controls. The present study investigates depolarization of smooth muscle cell membranes through direct determination of the membrane potential in the longitudinal duodenal smooth muscle isolated from the two rat strains. Membrane potentials were not different in the two groups: -64.0 +/- 0.5 mV (N = 86) (means +/- SEM) in SHR and -62.0 +/- 3.0 mV (N = 95) in the WKY group. However, when the electrogenic contribution of Na/K-ATPase was abolished by removing potassium from the extracellular medium, the membrane potentials differed significantly: -35.0 +/- 1.0 mV (N = 45) and -28.0 +/- 1.0 mV (N = 48) for SHR and WKY, respectively. The lower depolarization observed in the duodena isolated from SHR is a further indication that the sodium pump is inhibited in these animals.