The use of a steric parameter (Yγ) in QSAR calculations for peptide hormones

A steric parameter (Y_γ) has been derived for α-amino acids to characterize the steric hindrances near to the α-carbon atom. This easily computable variable is suitable for quantitative structure-activity relationship (QSAR) calculations for peptide hormones. Successful multivariate analyses were performed for oxytocin and angiotensin II analogs with the help of parameters describing the lipophilic and steric properties and the measure of dispersion forces. In the case of position 4 substituted oxytocin analogs, the steric, lipophilic and H-bridge forming properties equally account for the different biological activities of the derivatives. In the case of position 5 substituted angiotensin II analogs, primarily the steric parameters account for the biological activity of the series of derivatives.     

Theoretical conformational analysis of Asn1, Val5 angiotensin II

A theoretical analysis of the conformation of the octapeptide hormone Asn¹, Val⁵ angiotensin II has been carried out by semiempirical potential energy calculations. A preliminary study of the Ala₆-Pro-Ala molecule, which mimics the angiotensin backbone, provided us with likely backbone structures on which the effect of the full side chains of the hormone could be assessed. For angiotensin II, the calculations show that only a small number of folded, compact conformations have a high probability of existence. This is the consequence of favorable packing and of the presence of proline in position 7. These results are consistent with various experimental data, both structural and biological. This method is readily applicable to the study of analogs of the hormone or to other peptides of comparable size.     

The Importance of Ring Size and Position for the Antiplasmodial Activity of Angiotensin II Restricted Analogs

Malaria is caused by the protozoa Plasmodium and is responsible for approximately one million deaths annually. The antimalarial effects of angiotensin II and its analogs against Plasmodium gallinaceum and falciparum have recently been reported. Here, 12 angiotensin II restricted analogs that contain i ? (i + 2), i ? (i + 3) and i ? (i + 4) lactam bridges were synthesized to analyze their effect on antiplasmodial activity. To accomplish this, peptides containing two amino acid residues (aspartic or glutamic acids and lysine or ornithine), were synthesized by the t-Boc solid phase method, purified by liquid chromatography, and characterized by mass spectrometry, and conformational studies were performed by circular dichroism. The results indicate that some of the analogs had anti-plasmodium activity similar to angiotensin II (88 % activity). Among those, eight compounds exhibited high activity (>70 %), measured by fluorescence microscopy. The analogs with smaller lactam rings and an aspartic acid residue as the bridgehead element had lower levels of lytic activity. The results obtained with the new restricted analogs showed that the insertion position (near the N-terminus), the ring size, and the number of residues between the rings are as important as the components of lactam bridge, regardless of their chirality. The circular dichroism studies suggest that the active analogs, and native angiotensin II, adopt a β-fold conformation in different solutions. In conclusion, this approach provides insight for understanding the effects of restricting the ring size and position on the bioactivity of angiotensin II and provides a new direction for the design of potential chemotherapeutic agents.     

Conformation and activity in angiotensin II peptides

Angiotensin II and its competitive inhibitor [Sar¹, Ile⁸]-angiotensin II, as well as several analogs of these two compounds specifically chosen for their well-defined pharmacological properties, were studied by circular dichroism and nuclear magnetic resonance methods at various pH values in aqueous solution and in d₆-dimethylsulfoxide. The results were compared with their biological activities. This allowed us to establish relationships between conformation and pressor activity, explaining most of the properties of angiotensin II, its inhibitor, and the analogs successively substituted in positions 3 and 5.     

Antagonists of angiotensin II containing N-methyl-L-alanine and DL-nipecotic acid in position 7.

[1-sarcosine, 7-N-methyl-L-alanine, 8-isoleucine]-Angiotensin II and [1-sarcosine, 7-DL-nipecotic acid, 8-isoleucine]-angiotensin II were synthesized by the solid-phase method and purified by cation-exchange chromatography and high-pressure liquid chromatography. In the isolated rat uterus these analogs and less than 0.1% of the myotropic activity of angiotensin II and inhibited angiotensin II with pA2 values of 8.2 and 7.8, respectively. In the rat pressor assay (vagotomized ganglion blocked rat) these analogs had 0.9 and 2.8%, respectively, of the pressor activity of angiotensin II. The results show that the proline residue in position 7 of [Sar1,Ile8]-angiotensin II may be replaced by other secondary amino acids without disrupting interactions at angiotensin II receptors.     

Mechanisms and sites of action of newer angiotensin agonists and antagonists in terms of activity and receptor.

From the myotropic and vasopressor activities of the numerous analogs of angiotensin II, it has been determined that the phenyl group of position 8 possesses the information for biologic response while the aromatic side groups in positions 4 and 6, the guanido group in position 2 and the C-terminal carboxyl are involved in binding to the receptor site. Removal of a side group of the C-terminal phenyalanine yields peptides that bind to the receptor. While many of these have low agonist properties, all have antagonist properties. Modifications in the aromatic side groups affect conformation of the octapeptide. This change may relate to receptor binding but sufficient data are not yet available to determine a correlation pattern. A proposed conformation for angiotensin is given as well as an artist's concept of angiotensin II binding to its membrane receptor utilizing the groups known to be involved in binding. Both angiotensin II and III [des-Asp] angiotensin II stimulate the biosynthesis and release of aldosterone from adrenal glomerulosa cells. Sufficient data are not yet available to determine whether the conversion of angiotensin II to angiotensin III is neccessary for the steroidogenesis activity.     

Photoaffinity labeling of the angiotensin II receptor; pharmacology of the labeling peptides in the dark.

The biological activities of photoaffinity labeling analogs of angiotensin II (ATII) and their precursors were measured in rabbit aorta strips in the dark. Most of the analogs behave as reversible, specific agonists, one as a competitive inhibitor. The activities are discussed in line with the current view of structural requirements. The modifications consisted of substitutions on the aromatic nuclei of Tyr4 and Phe8 in [Sar1]ATII with (4'-NO2) Phe, (4'-NH2)Phe, (4'N3)Phe, (4'-N2 +)Phe, and (4'-NH2-3', 5'-I2)Phe. It is shown that the affinity of the ATII analogs modified in position 4 depends on the electronegativity and not on space-filling properties of the aromatic residue; rising electronegativity lowers the affinity, i.e. [sar1, (4'-NO2)Phe4]ATII has no more measurable activity. Substituting the aromatic side chain in position 8 of [Sar1]ATII gives well-binding analogs with intrinsic activities from 0 to 100% and activity seems to depend only on stereochemical requirements. Agonists and partial agonists bear rather small groups like -NH2, -N3, -NO2, and -N2 +. The only antagonist [Sar1, (4'-NH2-3',5'-I2)Phe8]ATII resembles the antagonist E1Sar1, Leu8]ATII in competitivity and binding.     

Structure, biological activity and membrane partitioning of analogs of the isoprenylated a-factor mating peptide of Saccharomyces cerevisiae.

Previous biochemical investigations on the Saccharomyces cerevisiae a-factor indicated that this lipopeptide pheromone [YIIKGVFWDPAC(farnesyl)OMe] might adopt a type II beta-turn at positions 4 and 5 of the peptide sequence. To test this hypothesis, we synthesized five analogs of a-factor, in which residues at positions 4 and 5 were replaced with: L-Pro4(I); D-Pro4(II); L-Pro4-D-Ala5(III); D-Pro4-L-Ala5(IV); or Nle4(V). Analogs were purified to > 99% homogeneity as evidenced by HPLC and TLC and were characterized by mass spectrometry and amino acid analysis. Using a growth arrest assay the conformationally restricted a-factor analogs I and III were found to be almost 50-fold more active than the diastereometric homologs II and IV and were equally active to wild-type a-factor. Replacement of Lys4 with the isosteric Nle4 almost abolished the activity of the pheromone. Thus, the incorporation of residues that promote a type II beta-turn compensated for the loss of the favorable contribution of the Lys4 side chain to pheromone activity. CD spectra on these peptides suggested that they were essentially disordered in both TFE/H2O and in the presence of DMPC vesicles. There was no correlation between CD peak shape and biological activity. Using fluorescence spectroscopy we measured the interaction of lipid vesicles with these position 4 and 5 analogs as well as with three a-factor analogs with a modified farnesyl group. The results indicated that modifications of both the peptide sequence and the lipid moiety affect partitioning into lipid, and that no correlation existed between the propensity of a pheromone to partition into the lipid and its biological activity.     

Synthesis and biological activities of angiotensin II and Sarmesin analogues containing cyclohexylalanine

Analogues of angiotensin II with cyclohexylalanine (Cha) at position 4 or 8, and analogues of the competitive (type II) angiotensin antagonist [Sar1,Tyr(Me)4]ANG II (Sarmesin) with Cha at position 8, have been prepared by the solid phase method and purified by reversed-phase HPLC. Analogues of ANG II with Cha at position 8 in which the position 1 residue was substituted with sarcosine (Sar) or amino-isobutyric acid (Aib) or was deleted (Des), were slowly reversing (Type I) antagonists with "pA2" values in the rat isolated uterus assay of approximately 8.5. The additional substitution of Tyr(Me) for Tyr at position 4 of these peptides gave reversible competitive (Type I/II) antagonists with pA2 values of 6.7, 5.8, and less than 5, while substitution of Phe for Tyr gave pA2 values of 7.4, 6.7, and less than 5, respectively. All 19 peptides synthesized in this study had low intrinsic agonist activity in the rat isolated uterus assay except for the type I antagonists [Sar1, Cha8]ANG II (7%), [Aib1, Cha8]ANG II (12%) and [Des1, Cha8]ANG II (20%). These data illustrate that the substitution of Cha at position 8 of ANG II analogues produces potent antagonists; however, Type I antagonists retain significant agonist activity whereas Type I/II antagonists do not. In contrast, substitution of Cha at position 4 in a variety of ANG II analogues resulted in severely diminished biological activity, illustrating that the presence of an aromatic ring quadrupole at position 4 is obligatory for receptor binding and activity.     

Structural analysis of the epitopes recognized by monoclonal antibodies to angiotensin II

Six clones were obtained that secrete anti-angiotensin II antibodies after somatic cell fusions between splenocytes of immunized BALB/c or outbred OF1 mice and NS-1 myeloma cells. The dissociation constants for angiotensin II ranged from 0.3 to 2.9 nM. A panel of 20 structural analogs of the hormone were used as probes to analyze the specificity of binding. From the binding studies and the putative three-dimensional structures of the tested peptides, three families of antibodies could be distinguished that recognized overlapping epitopes; the conservation of the native conformation of the angiotensin II molecule in the analogs appeared essential for the preservation of a high affinity to the antibodies. With one antibody, the affinities of the angiotensin II analogs have been correlated with their intrinsic biologic activities (as measured by in vivo pressor tests), and not with their binding affinity to the membrane receptor. These results are interpreted as mimicry, by the antibody binding site, of the active conformation of the receptor site.     

Design,synthesis and biological evaluation of cyclic angiotensin II analogues with 3,5 side-chain bridges. Role of C-terminal aromatic residue and ring cluster for activity and implications in the drug design of AT1 non-peptide antagonists

The novel amide linked angiotensin II (ANG II) cyclic analogues: gamma, epsilon -cyclo(3, 5)-[Sar(1)-Glu(3)-Lys(5)-Ile(8)] ANG II (I) and gamma, epsilon -cyclo(3, 5)-[Sar(1)-Glu(3)-Lys(5)-Phe(8)] ANG II (II) have been designed, synthesized and bioassayed in anesthetized rabbits in order to unravel structural ring cluster characteristics important for receptor activation. Analogue I with Ile at position 8 was an inhibitor of Angiotensin II while analogue II with Phe at position 8 was found to be an agonist. Similar results were reported for cyclic compounds that have reversed the linking between positions 3 and 5. The overall results show that positions 3 and 5 do not govern the biological activity of the synthetic analogues. It also appears that the aromatic ring cluster (Tyr-His-Phe) in agonist peptides is an essential stereo-electronic feature for Angiotensin II to exert its biological activity. A non-peptide mimetic of ANG II, 1-[2'-[(N-benzyl)tetrazol-5-yl]biphenyl-4-yl]methyl]-2-hydroxymethylbenzimidazole (BZI8) has been designed and synthesized. This molecule is more rigid and much less active than AT(1) non-peptide mimetic losartan probably because it lacks to mimic the orientation of tetrazole and the pharmacophore segments of butyl chain and imidazole ring.     

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.     

Cyclic insulin-regulated aminopeptidase (IRAP)/AT4 receptor ligands.

The angiotensin IV receptor (AT4 receptor) is the insulin-regulated aminopeptidase enzyme (IRAP, EC 3.4.11.3). This membrane-spanning enzyme belongs to the M1 family of zinc-dependent metallo-peptidases. It has been proposed that AT4 receptor ligands exert their physiological effects by binding to the active site of IRAP and thereby inhibiting the catalytic activity of the enzyme. The biological activity of a large series of linear angiotensin IV analogs was previously disclosed. Herein, the synthesis and biological evaluation of a series of angiotensin IV analogs, encompassing macrocyclic ring systems of different sizes, are presented. It is demonstrated that disulfide cyclizations of angiotensin IV can deliver ligands with high IRAP/AT4 receptor affinity. One ligand, with an 11-membered ring system (4), inhibited human IRAP and aminopeptidase N (AP-N) activity with similar potency as angiotensin IV but was considerably more stable than angiotensin IV toward enzymatic degradation. The compound provides a promising starting point for further optimization toward more drug-like derivatives. The cyclic constrained analogs allowed us to propose a tentative bioactive conformation of angiotensin IV and it seems that the peptide adopts an inverse gamma-turn at the C-terminal.     

Synthesis, Biological Properties, and Structure-Activity Relationships of Quinoxaline Angiotensin II Receptor Antagonists

Quinoxaline heterocycle containing angiotensin II receptor antagonist analogs were prepared. All five analogs reported here display potent antagonistic activities and most interestingly, quinozaline bis-N-oxide 10 exhibits very potent activities both in binding and functional assays.     

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.     

The effect of modifications of the A5 and A19 amino acid residues on the biological activity of insulin. [Leu5-A] and [Phe19-A] sheep insulins

Two analogs of sheep insulin, both differing from the native material by a single amino acid in the A chain, have been synthesized and isolated in highly purified form by procedures developed in this laboratory. In one case, the glutamine residue in position A⁵ was replaced by leucine ([Leu⁵-A]); in the other, the tyrosine residue in position A¹⁹ was replaced by phenylalanine ([Phe¹⁹-A]). The biological behavior of these analogs was compared with natural bovine insulin inin vitro tests and in receptor-binding assays, as well as in radioimmunoassay. In the stimulation of glucose oxidation by rat adipocytes, the analogs gave relative potencies of 30% and 7.8% for [Leu⁵-A] and [Phe¹⁹-A], respectively. Receptor-binding assays in rat liver plasma membranes showed similar behavior for both analogs. In radioimmunoassay, [Leu⁵-A] displayed a relative potency of 27.9%, while [Phe¹⁹-A] showed a relative potency of 19–27%, compared with bovine insulin. At high concentration, both analogs displayed the same maximal activity as bovine insulin, and the dose-response curves are essentially parallel. It is speculated that the interaction between the glutamine residue in position 5 and the tyrosine residue in position 19 of the A chain of insulin are important in maintaining a three-dimensional structure commensurate with high biological activity. The full intrinsic activity of both analogs at high concentrations and the similarity of the potency figures in receptor-binding and glucose-oxidation assays permit the further conclusion that the reduced potency in the latter assay can be ascribed wholly to the reduced binding affinity toward insulin receptors caused by the substitutions made in the analogs. The receptor-analog complexes are fully capable of triggering the next event in the chain leading to the biological response.     

Evidence for angiotensin II receptors in the urinary bladder of the rabbit

Dose-response (DR) curves for several angiotensin analogs were examined on isolated rabbit detrusor strips with washout and rest between each addition. The order of potency was [Val5]-angiotensin II greater than [Ile5]-angiotensin II greater than [Ile5]-angiotensin I greater than [Val4]-angiotensin III. Repeated cumulative DR to [Val5]-AII resulted in a gradual increase in potency and intrinsic activity for four DR. However, the maximum force generated occurred at lower agonist concentrations and was less than that of the single methods, suggesting tachyphylaxis. Atropine (1.0 microM) shifted the cumulative DR curve downward, suggesting some cholinergic component possibly involving a presynaptic site of action. The magnitude of field-stimulated atropine-resistant contractions was reduced by both 1.0 and 10 microM saralasin as well as 10 microM naloxone. Tissue binding with 125I-labelled angiotensin II on isolated detrusor smooth muscle membranes indicated specific binding saturation occurred at 14.3 fmol/mg with a KD of 0.72 nM in EDTA-Tris buffered saline. Thus our results show that angiotensin II (AII) receptors can be demonstrated in destrusor muscle by ligand binding experiments on cell membranes and that saralasin and naloxone partially block atropine-resistant contractions. However, it seems unlikely that AII serves as a neurotransmitter because of the delay in onset of action of exogenous AII in isolated bath experiments and the apparent inability of saralasin to totally abolish the atropine-resistant field-stimulated preparation. If AII serves a role in neurotransmission it most probably is as a neuromodulator.     

A recombinant rat vascular AT1 receptor confers growth properties to angiotensin II in Chinese hamster ovary cells.

A rat vascular AT1 receptor cDNA has been stably expressed into Chinese Hamster Ovary cells and the resulting recombinant AT1a receptor has been functionally characterized. This receptor binds 125I Sar1-angiotensin II with an affinity of 0.9 nM and the displacement of this ligand by a series of peptidic and nonpeptidic analogs is shown. Binding of angiotensin II to this receptor causes a rapid increase in inositol phosphate production, whereas this effect is not observed in nontransfected cells. Des-aspartyl1 angiotensin II and at a lesser extent angiotensin I are also able to produce an increase in inositol phosphates. More importantly, the actions of angiotensin II on cell division were clearly demonstrated in this model, since angiotensin II is able to stimulate DNA synthesis by 400% and double the cell population of the transfected cells in 36 hours in the absence of any other growth factor, whereas no effect is observed in nontransfected cells.     

Isolation and purification of angiotensin II using affinity and high-pressure liquid chromatography

Peptides have been found in a variety of tissues including brain. To purify the peptide angiotensin II, a three-step method for the isolation and purification has been developed using extraction, affinity chromatography, and high-pressure liquid chromatography. Angiotensin II antiserum purified by affinity chromatography was covalently coupled to Affi-gel 10 (Affi-gel 10-AB). The efficiency and usefulness of this column for the purification of angiotensin II from biological sources were tested with 125I- and 3H-labeled (Ile5)-angiotensin II added to rat brains prior to extraction. After extraction, the recoveries for both peptides were 74 and 75%, respectively. Recovery after the purification on Affi-gel 10-AB was 84 and 82%. Thirty-two percent of the radioactivity was not retained and 50% of the radioactivity could be eluted with 0.1 M Na citrate buffer containing 1 M NaCl using a stepwise pH gradient. Characterization by HPLC of the unretained radioactivity from the Affi-gel 10-AB column showed one peak for [125I]angiotensin II, coeluting with the [125I]angiotensin II standard and two minor peaks. Only 30% of unretained [3H]angiotensin II could be identified as intact [3H]angiotensin II on HPLC. Both [125I]angiotensin II and [3H]angiotensin II elutable at pH 5.0 and 4.0 on Affi-gel 10-AB could be demonstrated as highly purified [125I]angiotensin II and [3H]angiotensin II on HPLC with a purity of more than 90%. On HPLC, the recovery was 81% for [125I]angiotensin II and 99% for [3H]angiotensin II. The recovery for the entire three-step procedure was about 60%. The loading capacity of the Affi-gel 10-AB column for (Ile5)-angiotensin II was 550 ng.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biological and conformational studies of [Val4]morphiceptin and [D-Val4]morphiceptin analogs incorporating cis-2-aminocyclopentane carboxylic acid as a peptidomimetic for proline

We report the synthesis, biological activity, and conformational analysis of tetrapeptide analogs related to [Val4]morphiceptin and [D-Val4]morphiceptin in which the proline at the second position has been replaced with cis-2-aminocyclopentane carboxylic acid (cis-2-Ac5c). Since the cis-2-Ac5c residue contains a normal amide, only the trans form has been observed about the amide bond between the first and second residues. The cis-2-Ac5c is a beta amino acid with two chiral centers resulting in two possible configurational isomers, namely (1S, 2R) and 1R, 2S) forms. The analogs containing the (1S, 2R)-Ac5c residue show activity at the mu-receptor but are inactive at the delta-receptor, resulting in a high selectivity for the mu-receptor. The (1R,2S)-Ac5c containing analogs are completely inactive at both the mu- and delta-receptors. The conformational analysis indicates that the separation of the aromatic rings of the tyrosine and phenylalanine residues, as expressed by the center-to-center distance, is 10.1-12.7 A for the preferred conformations of the bioactive analogs containing the (1S,2R)-Ac5c residue while a range of 4.8-7.0 A is observed for the preferred conformations of the inactive analogs with the (IR,2S)-Ac5c residue. A comparison of the findings from the conformational analysis and biological assays establishes the fact that a relatively large separation of the two aromatic side chains is required for the mu-opioid receptor activity of these molecules. Since the tetrapeptide amides studied in this investigation show similar biological profiles to those of the morphiceptin-related analogs, we have compared the preferred conformations estimated for the cis-2-Ac5c containing analogs with those of morphiceptin. One of the low energy conformations calculated for morphiceptin with the cis form about the tyrosine and proline residues has considerable topological similarity with the bioactive analogs containing the (1S,2R)-Ac5c residue, indicating that the cis from about these two residues is required for the biological activity of the morphiceptin-related analogs containing the proline at the second position.