The design and synthesis of a potent Angiotensin II cyclic analogue confirms the ring cluster receptor conformation of the hormone Angiotensin II.

The novel amide linked Angiotensin II potent cyclic analogue, c-[Sar1,Lys3,Glu5] ANG II 19 has been designed and synthesized in an attempt to test the aromatic ring clustering and the charge relay bioactive conformation we have recently suggested for ANG II. This constrained cyclic analogue was synthesized by connecting the Lys3 amino and Glu5 carboxyl side chain groups, and it was found to be potent in the rat uterus assay and in anesthetized rabbits. The central part of the molecule is fixed covalently in the conformation predicted according to the backbone bend conformational model proposed for Angiotensin II. The obtained results using a combination of 2D NMR, 1D NOE spectroscopy and molecular modeling revealed a similar Tyr4-Ile5-His6 bend, a His6-Pro7 trans configuration and a side chain aromatic ring cluster of the key aminoacids Tyr4, His6, Phe8 for c-[Sar1,Lys3,Glu5] ANG II as it has been found for ANG II (Matsoukas, J. H.; Hondrelis, J.; Keramida, M.; Mavromoustakos, T.; Markriyannis, A.; Yamdagni, R.; Wu, Q.; Moore, G. J. J. Biol. Chem. 1994, 269, 5303). Previous study of the conformational properties of the Angiotensin II type I antagonist [Hser(gamma-OMe)8] ANG II (Matsoukas, J. M.; Agelis, G.; Wahhab, A.; Hondrelis, J.; Panagiotopoulos. D.; Yamdagni, R.; Wu, Q.; Mavromoustakos, T.; Maia, H.; Ganter, R.; Moore, G. J. J. Med. Chem. 1995, 38, 4660) using 1-D NOE spectroscopy coupled with the present study of the same type of lead antagonist Sarilesin revealed that the Tyr4-Ile5-His6 bend, a conformational property found in Angiotensin II is not present in type I antagonists. The obtained results provide an important conformational difference between Angiotensin II agonists and type I antagonists. It appears that our synthetic attempt to further support our proposed model was successful and points out that the charge relay system and aromatic ring cluster are essential stereoelectronic features for Angiotensin II to exert its biological activity.

Conformational analysis of the thrombin receptor agonist peptides SFLLR and SFLLR-NH2 by NMR: evidence for a cyclic bioactive conformation.

The conformational properties of the pentapeptide Ser-Phe-Leu-Leu-Arg (P5), a human thrombin receptor-derived sequence forming part of a tethered ligand which activates the thrombin receptor, and its more active amide derivative Ser-Phe-Leu-Leu-Arg-NH2 (P5-NH2), have been studied by proton NMR spectroscopy in dimethylsulfoxide. Measurements of nuclear Overhauser effects, performed using two-dimensional rotating frame nuclear Overhauser (ROESY) and one-dimensional nuclear Overhauser enhancement (NOE) spectroscopy, revealed that P5 exists mainly in an extended conformation. However, proton-proton 1D-NOEs between Phe C alpha H and Ser C alpha H Leu3 C alpha H and Leu3 NH, and Leu4 C alpha H and Leu4 NH, as well as between the Ser and Arg sidechains, also implicated a minor conformer for P5 having a curved backbone and a near-cyclic structure. In contrast to P5, measurements of NOEs and ROEs for P5-NH2 revealed a more stabilized cyclic structure which may account for its higher biological potency. Thus strong interresidue sequential NH (i)-NH (i + 1) interactions, as well as C-terminal carboxamide to N-terminal side-chain interactions, i.e., Arg CONH2 to Phe ring and Arg CONH2 to Ser C alpha/C beta beta', observed at lower levels of the ROESY spectrum, supported a curved backbone structure for SFLLR-NH2. Since the higher potency P5-NH2 analogue adopts predominantly a cyclic structure, a cyclic bioactive conformation for thrombin receptor agonist peptides is suggested.

Synthesis and contractile activities of cyclic thrombin receptor-derived peptide analogues with a Phe-Leu-Leu-Arg motif: importance of the Phe/Arg relative conformation and the primary amino group for activity.

Based on the minimal peptide sequence (Phe-Leu-Leu-Arg) that has been found to exhibit biological activity in a gastric smooth muscle contractile assay for thrombin receptor-activating peptides, the cyclic peptide analogues cyclo(Phe-Leu-Leu-Arg-Acp) (1), cyclo(Phe-Leu-Leu-Arg-epsilon Lys) (2), and cyclo(Phe-Leu-Leu-Arg-Gly) (3) have been synthesized by the solid-phase method using benzotriazol-1-yloxytris(dimethylamino)phosphonium hexafluoroborate or 2-(1H-benzo-triazol-1-yl)-1,1,3,3-tetramethyluronium tetrafluoroborate as cyclization reagents. The contractile activities of compounds 1-3 have been compared with that of the linear thrombin receptor-activating peptide (TRAP) Ser-Phe-Leu-Leu-Arg-NH2 (compound 4) using a gastric smooth muscle strip assay. Compound 2, wherein the epsilon-amino group of lysine was coupled to the alpha-carboxyl of arginine, exhibited a contractile activity comparable to that of the linear TRAP, compound 4. However compound 1, wherein the aminocaproic linker group yielded a ring size the same as for compound 2 but without a primary amino group, exhibited a contractile activity 600-1000-fold lower than compounds 2 and 4. Compound 3, which exhibited partial agonist activity, was about 100-fold less potent than either compound 2 or 4. NMR spectroscopy of compound 2 revealed a proximity of the Phe and Arg side chains, leading to a molecular model generated by distance geometry and molecular dynamics, wherein the Phe and Arg residues are shown in proximity on the same side of the peptide ring. We conclude that the Phe and Arg side chains along with the primary amino group form an active recognition motif that is augmented by the presence of a primary amino group in the cyclic peptide. We suggest that a comparable cyclic conformation may be responsible for the interaction of linear TRAPs with the thrombin receptor.

Differences in backbone structure between angiotensin II agonists and type I antagonists.

Type I angiotensin II antagonists with O-methyl-L-homoserine [HSer(gamma-OMe)] and delta-methoxy-L-norvaline [Nva(delta-OMe)] at position 8 have been prepared by the solid-phase method, purified by reverse-phase HPLC, and bioassayed in the rat uterus, and their backbone conformational properties were investigated by nuclear Overhauser effect (NOE) spectroscopy. [Sar1,HSer-(gamma-OMe)8]ANGII, [HSer(gamma-OMe)8]ANGII, [Des1,HSer(gamma-OMe)8]ANGII, [Sar1,Nva(delta-OMe)8]-ANGII, and [Des1,Nva(delta-OMe)8]ANGII had, respectively, the following antagonist activities, pA2: 7.6, 7.5, < 6.0, 7.1, and 6.9. Analogs of [Sar1]ANGII with delta-hydroxy-L-norvaline [Nva(delta-OH)], delta-methoxy-L-norvaline [Nva(delta-OMe)], 4'-carboxyphenylalanine [Phe(4'-COOH)], and 4'-(trifluoromethyl)phenylalanine [Phe(4'-CF3)] at position 4 were also prepared by solid phase and bioassayed in the rat uterus. [Sar1,Nva(delta-OH)4]ANGII, [Aib1,Nva(delta-OMe)4]ANGII, [Sar1,DL-Phe(4'-COOH)4]ANGII, and [Sar1,DL-Phe(4'-CF3)4]ANGII had, respectively, agonist activities as follows: 4%, 1.5%, 3%, < 0.1%, and < 0.1%. These data emphasize that replacement of Ile8 in Sarilesin with the higher homologs HSer(gamma-OMe) and Nva(delta-OMe) does not greatly alter the structural requirements necessary for expression of type I antagonist activity, while replacement of the tyrosine hydroxyl in [Sar1]ANGII by the carboxylate or the trifluoromethyl group abolishes activity, suggesting that the tyrosinate pharmacophore cannot be replaced by any negatively charged or electronegative group. Conformational investigation of the ANGII type I antagonists [HSer(gamma-OMe)8]ANGII and [Sar1Nva(delta-OMe)8]ANGII in DMSO by 1D-NOE spectroscopy revealed that the Tyr-Ile-His bend, a conformational property found in ANGII and [Sar1]ANGII (J. Biol. Chem. 1994, 269, 5303) is not present in type I antagonists, providing for the first time an important conformational difference between angiotensin II agonists and type I antagonists.

Role of the NH2-terminal domain of angiotensin II (ANG II) and [Sar1]angiotensin II on conformation and activity. NMR evidence for aromatic ring clustering and peptide backbone folding compared with [des-1,2,3]angiotensin II.

The role of the NH2 termini of angiotensin II (ANG II) and [Sar1]ANG II on conformation and activity were examined by proton NMR two-dimensional-J-correlated spectroscopy and one-dimensional nuclear Overhauser effect studies in the relatively nonpolar "receptor-simulating" environment provided by dimethyl sulfoxide-d6, using the biologically inactive COOH-terminal pentapeptide [des1,2,3]ANG II as control. Irradiation of C alpha H, C2H, and C4H proton resonances in ANG II and [Sar1]ANG II resulted in enhancements of Tyr and Phe ring proton resonances, indicating that the three aromatic rings cluster together. Very strong enhancements (17-22%) of the C alpha Y proton resonance in ANG II and [Sar1]ANG II upon irradiation of the C alpha H proton resonance, and vice versa, revealed that a Tyr-Ile-His bend is a predominant feature of the conformation of the two agonists. In contrast, saturation of the C alpha H and C alpha Y proton resonances in the control pentapeptide [des-1,2,3]ANG II did not produce, respectively, any C alpha Y or C alpha H proton nuclear Overhauser effect enhancement, illustrating the absence of a Tyr-Ile-His bend in the truncated ANG II peptide. The present findings indicate that the NH2-terminal domain of ANG II appears to have an essential role in generating the biologically active charge relay conformation of the hormone.

Synthesis and biological activities of angiotensin II, Sarilesin, and Sarmesin analogues containing Aze or Pip at position 7.

Analogues of [Sar1]angiotensin II, Sarilesin (type I antagonist), and Sarmesin (type II antagonist) with L-azetidine-2-carboxylic acid (Aze) and L-pipecolic acid (Pip) at position 7 have been prepared by the solid-phase method, purified by reverse-phase HPLC, and bioassayed in the rat uterus. Analogues of the superagonist [Sar1]ANGII with Aze or Pip at position 7 and sarcosine (Sar) or aminoisobutyric acid (Aib) at position 1 had high intrinsic activity in the rat isolated uterus assay (34-184%). Analogues of Sarilesin ([Sar1,Ile8]ANGII) with Aze or Pip at position 7 and Sar or Aib at position 1 retained high antagonist activity (pA2 = 7.1-8.3). Analogues of Sarmesin ([Sar1,Tyr-(OMe)4]ANGII) with Aze and Pip at position 7 had pA2 values of 7.4 and 6.5, respectively. [Aze7]-ANGII and [Pip7]ANGII had low activities (12% and 1%, respectively), and deletion of Sar at position 1 of Sarmesin analogues abolished binding (or affinity) as judged from pA2 values. Nuclear Overhauser effect (NOE) spectroscopy studies of [Sar1,Aze7]ANGII in DMSO-d6 have indicated a clustering of the three aromatic rings (Tyr, His, Phe) and proximity of Sar C alpha and Arg C delta protons to the Tyr/Phe ring protons. These data emphasize that replacement of Pro with the lower and higher homologs Aze and Pip does not greatly alter the structural requirements necessary for expression of agonist or antagonist activity, when sarcosine occupies position 1, but not when Asp occupies position 1, suggesting that there is an intimate relationship between the N-terminal and penultimate residues of the molecule in the biologically active conformation of the molecule.

1H-NMR studies of sarmesin and [des1]sarmesin conformation in dimethylsulfoxide by nuclear Overhauser effect (NOE) enhancement spectroscopy: folding of the N- and C-terminal domains.

The conformational properties of the competitive angiotensin II antagonist sarmesin [Sar-Arg-Val-Tyr(Me)-His-Pro-Phe] and its heptapeptide analogue [des1]sarmesin in dimethylsulphoxide-d6 were investigated by nuclear Overhauser effect (NOE) enhancement studies. Assignment of all backbone and side-chain protons was possible by combining information from intraresidue NOE studies with two-dimensional correlated spectroscopy (COSY) studies. Saturation of the His C alpha proton of sarmesin produced essentially the same interresidue NOE enhancement of the two Pro C delta protons, illustrating the presence of the trans His-Pro bond. Saturation of the Sar N-methyl group caused enhancement of one of the His C beta protons, suggesting the presence of a turn in the N-terminal region of the molecule. Saturation of His C2 in sarmesin and [des1]sarmesin enhanced the Tyr(Me) methyl signal. Saturation of the Tyr(Me) methyl protons in [des1]sarmesin produced NOE enhancement of the His C2 and C4 protons, and saturation of the His C2 proton enhanced the Tyr(Me) meta and ortho proton signals. Interresidue interactions between the Tyr(Me) and His protons in sarmesin and [des1]sarmesin illustrate that these two side-chains remain in close proximity even in the absence of the postulated hydrogen bond between Tyr hydroxyl and the His imidazole ring in angiotensin II. The data suggest a preferred conformation for sarmesin in DMSO in which the peptide backbone is S-shaped and similar to that for angiotensin II.