The importance of the N-terminal beta-turn in bradykinin antagonists

Three peptides, B-10148 (Lys-1-Lys0-Arg1-Pro2-Hyp3-Gly4-Igl5-Ser6- DF5F7-Oic8; where Hyp is trans-4-hydroxyproline, Igl is alpha-(2-indanyl)glycine, F5F is 2,3,4,5,6-pentafluorophenylalanine and Oic is (3aS,7aS)-octahydroindole-2-carboxylic acid), B-10206 (DArg0-Arg1-Pro2-Hyp3-Gly4-Igl5-Ser6-DF 5F7-Nc7G8-Arg9; where Nc7G is N-cycloheptylglycine) and B- 10284 (Arg1-Pro2-Pro3-Gly4-Phe5-Thr6-DTic7-Oic8- NH2; where Tic is 1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid), were studied in detail by NMR spectroscopy in 60% CD3OH /40% H2O and modeled by a simulated annealing protocol to determine their solution structure. B-10148, an extremely potent BK B1 receptor antagonist with very high BK B2 receptor antagonist activity, despite lacking a C-terminal Arg, displayed an ideal type II beta-turn from Pro2 to Igl5, as well as a salt bridge between the guanidino group of Arg1 and the carboXylate group of Oic8. B-10206, the most potent B2 antagonist, also displayed an ideal type II beta-turn from Pro2 to Igl5 but secondary structure was not observed at the C-terminal end. The third peptide, B-10284, a des-Arg9 analog with a C-terminal amide and a very potent B2 antagonist, had no definite solution structure. The high activity of these peptides emphasizes the importance of the N-terminal beta-turn and the hydrophobic character at the C-terminus in determining the activity of bradykinin antagonists.     

Enzymatic inactivation of bradykinin by rat brain neuronal perikarya

1. Bradykinin (Bk; Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg8) inactivation by bulk isolated neurons from rat brain is described. 2. Bk is rapidly inactivated by neuronal perikarya (4.2 +/- 0.6 fmol/min/cell body). 3. Sites of inactivating cleavages, determined by a kininase bioassay combined with a time-course Bk-product analysis, were the Phe5-Ser6, Pro7-Phe8, Gly4-Phe5, and Pro3-Gly4 peptide bonds. The cleavage of the Phe5-Ser6 bond inactivated Bk at least five fold faster than the other observed cleavages. 4. Inactivating peptidases were identified by the effect of inhibitors on Bk-product formation. The Phe5-Ser6 bond cleavage is attributed mainly to a calcium-activated thiol-endopeptidase, a predominantly soluble enzyme which did not behave as a metalloenzyme upon dialysis and was strongly inhibited by N-[1(R,S)-carboxy-2-phenylethyl]-Ala-Ala-Phe-p-aminobenzoate and endo-oligopeptidase A antiserum. Thus, neuronal perikarya thiol-endopeptidase seems to differ from endo-oligopeptidase A and endopeptidase 24.15. 5. Endopeptidase 24.11 cleaves Bk at the Gly4-Phe5 and, to a larger extent, at the Pro7-Phe8 bond. The latter bond is also cleaved by angiotensin-converting enzyme (ACE) and prolyl endopeptidase (PE). PE also hydrolyzes Bk at the Pro3-Gly4 bond. 6. Secondary processing of Bk inactivation products occurs by (1) a rapid cleavage of Ser6-Pro7-Phe8-Arg8 at the Pro7-Phe8 bond by endopeptidase 24.11, 3820ACE, and PE; (2) a bestatin-sensitive breakdown of Phe8-Arg9; and (3) conversion of Arg1-Pro7 to Arg1-Phe5, of Gly4-Arg9 to both Gly4-Pro7 and Ser6-Arg9, and of Phe5-Arg9 to Ser6-Arg9, Phe8-Arg9, and Ser6-Pro7, by unidentified peptidases. 7. A model for the enzymatic inactivation of bradykinin by rat brain neuronal perikarya is proposed.     

Beta-turns induced in bradykinin by (S)-alpha-methylproline.

The ability of (S)-alpha-methylproline (alpha-MePro) to stabilise reverse-turn conformations in the peptide hormone bradykinin (BK = Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9) has been investigated. Two BK analogues containing alpha-MePro at position 3 or position 7 were synthesised and their conformations in aqueous solution investigated by NMR spectroscopy. Whereas BK is largely disordered on the NMR time scale both analogues showed ROE connectivities in 2D-ROESY spectra indicative of reverse-turn conformations at both Pro2-Phe5 and Ser6-Arg9, whose formation appears to be cooperative. Some potential applications of alpha-MePro as a reverse-turn mimetic in the construction of synthetic peptide libraries is discussed.     

Structural recognition of an ICAM-1 peptide by its receptor on the surface of T cells: conformational studies of cyclo (1, 12)-Pen-Pro-Arg-Gly-Gly-Ser-Val-Leu-Val-Thr-Gly-Cys-OH.

The purpose of this study is to elucidate the solution conformation of cyclic peptide 1 (cIBR), cyclo (1, 12)-Pen1-Pro2-Arg3-Gly4-Gly5-Ser6-Val7-Leu8-V al9-Thr10-Gly11-Cys12-OH, using NMR, circular dichroism (CD) and molecular dynamics (MD) simulation experiments. cIBR peptide (1), which is derived from the sequence of intercellular adhesion molecule-1 (ICAM-1, CD54), inhibits homotypic T-cell adhesion in vitro. The peptide hinders T-cell adhesion by inhibiting the leukocyte function-associated antigen-1 (LFA-1, CD11a/CD18) interaction with ICAM-1. Furthermore, Molt-3 T cells bind and internalize this peptide via cell surface receptors such as LFA-1. Peptide internalization by the LFA-1 receptor is one possible mechanism of inhibition of T-cell adhesion. The recognition of the peptide by LFA-1 is due to its sequence and conformation; therefore, this study can provide a better understanding for the conformational requirement of peptide-receptor interactions. The solution structure of 1 was determined using NMR, CD and MD simulation in aqueous solution. NMR showed a major and a minor conformer due to the presence of cis/trans isomerization at the X-Pro peptide bond. Because the contribution of the minor conformer is very small, this work is focused only on the major conformer. In solution, the major conformer shows a trans-configuration at the Pen1-Pro2 peptide bond as determined by HMQC NMR. The major conformer shows possible beta-turns at Pro2-Arg3-Gly4-Gly5, Gly5-Ser6-Val7-Leu8, and Val9-Thr10-Gly11-Cys12. The first beta-turn is supported by the ROE connectivities between the NH of Gly4 and the NH of Gly5. The connectivities between the NH of Ser6 and the NH of Val7, followed by the interaction between the amide protons of Val7 and Leu8, support the presence of the second beta-turn. Furthermore, the presence of a beta-turn at Val9-Thr10-Gly11-Cys12 is supported by the NH-NH connectivities between Thr10 and Gly11 and between Gly11 and Cys12. The propensity to form a type I beta-turn structure is also supported by CD spectral analysis. The cIBR peptide (1) shows structural similarity at residues Pro2 to Val7 with the same sequence in the X-ray structure of D1-domain of ICAM-1. The conformation of Pro2 to Val7 in this peptide may be important for its binding selectivity to the LFA-1 receptor.     

Bradykinin analogs containing the 4-amino-2-benzazepin-3-one scaffold at the C-terminus.

High affinity peptide ligands for the bradykinin (BK) B(2) subtype receptor have been shown to adopt a beta-turn conformation of the C-terminal tetrapeptide (H-Arg(1)-Pro(2)-Pro(3)-Gly(4)-Phe(5)-Ser(6)-Pro(7)-Phe(8)-Arg(9)-OH). We investigated the replacement of the Pro(7)-Phe(8) dipeptide moiety in BK or the D-Tic(7)-Oic(8) subunit in HOE140 (H-D-Arg(0)-Arg(1)-Pro(2)-Hyp(3)-Gly(4)-Thi(5)-Ser(6)-D-Tic(7)-Oic(8)-Arg(9)-OH) by 4-amino-1,2,4,5-tetrahydro-2-benzazepin-3-one templates (Aba). Binding studies to the human B(2) receptor showed a correlation between the affinities of the BK analogs and the propensity of the templates to adopt a beta-turn conformation. The L-spiro-Aba-Gly containing HOE140 analog BK10 has the best affinity, which correlates with the known turn-inducing property of this template. All the compounds did not modify basal inositolphosphate (IP) output in B(2)-expressing CHO cells up to 10 microM concentration. The antagonist properties were confirmed by the guinea pig ileum smooth muscle contractility assay. The new amino-benzazepinone (Aba) substituted BK analogs were found to be surmountable antagonists.     

Correlation of secondary structures of bradykinin B1 receptor antagonists with their activity

The secondary structure of a bradykinin B(1)receptor antagonist B-10324 (F5C-Lys-(1)- Lys(0)-Arg(1)-Pro(2)- Hyp(3)-Gly(4)-CpG(5)- Ser(6)-DTic(7)-CpG(8)) was determined by NMR at 800MHz. The conformational data are compared with those obtained previously for two bradykinin B(1) receptor antagonists, namely B-9858 (Lys-(1)- Lys(0)-Arg(1)-Pro(2)- Hyp(3)-Gly(4)-Igl(5)- Ser(6)-DIgl(7)-Oic(8)) and B-10148 (Lys-(1)-Lys(0)-Arg(1)- Pro(2)-Hyp(3)-Gly(4)- Igl(5)-Ser(6)-DF5F(7)- Oic(8)). The abnormal amino acids are: Hyp, trans-4- hydroxyproline; Tic, 1, 2, 3, 4-tetrahydroisoquinoline-3-carboxylic acid; Oic, (2S, 3aS, 7aS)-octahydroindole-2-carboxylic acid; Igl, alpha(2- indanyl)glycine; F5F, 2,3,4,5,6-pentafluorophenylalanine; CpG, alpha- cyclopentylglycine. F5C, pentafluorocinnamoyl, is the N-terminal protecting group and is not involved in the peptide secondary structure. B-10324 contains an N-terminal Pro(2)- CpG(5) distorted type II beta-turn whereas the rest of the peptide is random. A salt bridge is not observed between the carboxylate group at the C-terminal end and the Arg(1) side chain, in contrast to that previously observed for B-9858 and B- 10148. The conformations are correlated with the measured B(1) receptor antagonist activities (J.-F. Larrivée, L. Gera, S. Houle, J. Bouthillier, D. R. Bachvarov, J. M. Stewart and F. Marc au, Br. J. Pharmacol. 131, 885-892 (2000)). The importance of the N-terminal beta-turn is highlighted.     

Nonpeptide antagonists for kinin receptors

Kinins are a family of small peptides acting as mediators of inflammation and pain in the peripheral and central nervous system. The two main 'kinins' in mammals are the nonapeptide bradykinin (BK, Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9) and the decapeptide kallidin (KD, [Lys0]-BK, Lys1-Arg2-Pro3-Pro4-Gly5-Phe6-Ser7-Pro8-Phe9- Arg10). Their biological actions are mediated by two distinct receptors, termed B1 and B2. Kinin B and B2 receptor antagonists may be useful drugs endowed with analgesic and anti-inflammatory properties, with potential use in asthma, allergic rhinitis and other diseases. The first nonpeptide kinin B2 receptor antagonist, WIN 64338, was reported in 1993. Despite its low selectivity, the compound provided a reference for pharmacological and modeling studies. Several quinoline and imidazo[1,2-a]pyridine derivatives have been shown by Fujisawa to possess high affinity and selectivity for kinin B2 receptors. Among them, FR 173657 displayed excellent in vitro and in vivo antagonistic activity, while FR 190997 emerged as the first nonpeptide agonist for B2 receptor. Two structurally related Fournier compounds were recently published. Other kinin B2 receptor ligands were obtained by rational design, through library screening or from natural sources. The only example of a nonpeptide kinin B1 receptor ligand has been reported in a patent by Sanofi.     

Degradation of bradykinin and its metabolites by rat brain synaptic membranes

Bradykinin (BK) (Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9) was degraded by rat brain synaptic membranes at a rate comparable to that found for Met-enkephalin, but approximately 40 times the rate for vasopressin and oxytocin. The catabolic pathway for BK and its metabolites was elucidated through the use of high performance liquid chromatography for metabolite identification and peptidase inhibitors for blocking specific cleavage sites. BK was hydrolyzed at three sites: at the -Phe5-Ser6- bond by metalloendopeptidase 24.15, at the -Pro7-Phe8- bond by an apparently novel peptidyl dipeptidase, and at the -Phe8-Arg9 bond by a carboxypeptidase B-like enzyme. Each enzyme contributed about equally to BK degradation under the assay conditions used. Some of the resulting metabolites were further hydrolyzed: BK(1-8) to BK(1-7) + Phe by a DFP inhibitable prolyl carboxypeptidase-like enzyme, BK(1-8) to BK(1-5) + BK(6-8) by metalloendopeptidase 24.15, BK(1-7) slowly to BK(1-5) by a second peptidyl dipeptidase which was captopril inhibited, and Phe-Arg to Phe + Arg by a bestatin-inhibited dipeptidase. A number of properties of the individual enzymes were determined including sensitivity to a variety of peptidase inhibitors. These results provide a starting point for investigating the potential physiological role of each enzyme in BK function in the brain.     

Study of bradykinin conformation in the presence of model membrane by Nuclear Magnetic Resonance and molecular modelling

The conformation of bradykinin (BK), Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9, was investigated by Nuclear Magnetic Resonance (NMR) spectroscopy and Monte Carlo simulation in two different media, i.e. in pure aqueous solution and in the presence of phospholipid vesicles. Monolamellar liposomes are a good model for biological membranes and mimic the environment experienced by bradykinin when interacting with G-protein coupled receptors (GPCRs). The NMR spectra showed that lipid bilayers induced a secondary structure in the otherwise inherently flexible peptide. The results of ensemble calculations revealed conformational changes occurring rapidly on the NMR time scale and allowed for the identification of different families of conformations that were averaged to reproduce the NMR observables. These structural results supported the hypothesis of the central role played by the peptide C-terminal domain in biological environments, and provided an explanation for the different biological behaviours observed for bradykinin.     

Isolation of brain endopeptidases: influence of size and sequence of substrates structurally related to bradykinin.

Two thiol-activated endopeptidases with pH optima near pH 7.5 were isolated from the supernatant fraction of rabbit brain homogenates by DEAE-cellulose chromatography, gel filtration and isoelectrofocusing. Peptide bond hydrolysis was measured quantitatively by ion-exchange chromatography with an amino acid analyzer. Brain kininase A hydrolyzes the Phe5-Ser6 peptide bond in bradykinin (Bk), Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9. It is isoelectric near pH 5.2 and has a molecular weight of approximately 71 000. The enzyme also hydrolyzes the Phe-Ser peptide bond in Lys-Bk, Met-Lys-Bk, des-Arg1-Bk, Lys9-Bk, Pro-Gly-Phe-Ser-Pro-Phe-Arg, and Gly-Pro-Phe-Ser-Pro-Phe-Arg, but does not hydrolyze (0.1%) this bond in des-Phe8-Arg9-Bk. Brain kininase B hydrolyzes the Pro7-Phe8 peptide bond in Bk. It is isoelectric at pH 4.9 and has a molecular weight of approximately 68 000. Brain kininase B also hydrolyzes the Pro-Phe bond in Lys-Bk, Met-Lys-Bk, Lys9-Bk, Ser-Pro-Phe-Arg, and Phe-Ser-Pro-Arg. Pretreatment of denatured kininogen with brain kininase A or B did not reduce the amount of trypsin-releasable Bk from this precursor protein, indicating that the Bk sequence, when part of a large protein, is not a substrate for either enzyme. However, kininase A and B hydrolyze the octadecapeptide Gly-Leu-Met-Lys-Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg-Ser-Val-Gin-Val. The data show that a large part of the C-terminal portion of bradykinin is important for the brain kininase A activity and, for both enzymes, the size of the peptide and presumably the residues adjacent to the scissle bond are important in determining the rate of peptide bond hydrolysis by these endopeptidases.     

Neuropeptide-Metabolizing Peptidases in Neuro-2a Neuroblastoma and C6 Glioma Cells

Mouse Neuro-2a neuroblastoma and rat C6 glioma cloned cells were screened for neuropeptide-metabolizing peptidases using a kininase bioassay combined with a time-course bradykinin-product analysis, and a fluorimetric assay for prolyl endopeptidase. The complementary peptide products Arg1----Phe5/Ser6----Arg9 and Arg1----Pro7/Phe8-Arg9 were released during bradykinin (Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9) inactivation by homogenates of Neuro-2a and C6 cells. The 1:1 stoichiometry of the complementary fragments and their high yields, at 10% bradykinin inactivation, demonstrated the sites of hydrolysis. The initial rate of Phe5-Ser6 bond cleavage was six-fold higher than that of the Pro7-Phe8 bond. These sites of cleavage can be attributed to enzymes similar to endopeptidase A (Phe5-Ser6) and prolyl endopeptidase (Pro7-Phe8) on the basis of the specificity and sensitivity to inhibitors of the kininase activity in Neuro-2a and C6 cell homogenates. Kininase and prolyl endopeptidase specific activities (fmol/min/cell) were 10.5 and 12.4 for Neuro-2a, and 1.5 and 2 for C6 homogenate, respectively. The recovery of kininase activity was 2.2-fold higher in the particulate than in the soluble (105,000 g for 1 h) neuronal fraction, whereas the amount of prolyl endopeptidase activity was about the same in both fractions. Kininase and prolyl endopeptidase activities in C6 cells were recovered mostly in the soluble fraction. Prolyl endopeptidase specific activity decreased 10-fold in serum-starved Neuro-2a cultured cells, with no change in activity in similarly treated C6 cells. In contrast, kininase specific activity in both cell types was essentially unaffected on serum-deprivation-induced differentiation.     

Structural characterization of lipopeptide agonists for the bradykinin B2 receptor

The conformational features of Pam-Lys(0)-Arg(1)-Pro(2)-Pro(3)-Gly(4)-Phe(5)-Ser(6)-Pro(7)-Phe(8)-Arg(9)-OH (PKD) and Pam-Gly(-1)-Lys(0)-Arg(1)-Pro(2)-Pro(3)-Gly(4)-Phe(5)-Ser(6)-Pro(7)-Phe(8)-Arg(9)-OH (PGKD), the Pam-Lys and Pam-Gly-Lys analogues of bradykinin, have been determined by high-resolution NMR in a zwitterionic lipoid environment. Radical-induced relaxation of the (1)H NMR signals was used to probe the topological orientation of the peptides with respect to the zwitterionic lipid interface. The radical-induced relaxation and molecular dynamics (MD) data indicated that the palmitic acid and N-terminal amino acid residues embed into the micelles, while the rest of the polypeptide chain is closely associated with the water-micelle interface. Throughout the entire nuclear Overhauser effect restrained MD simulation, a nonideal type I beta-turn was observed in the C-terminus of PKD between residues 6 and 9, and a gamma-turn was observed in the C-terminus of PGKD between residues 6 and 7. Therefore, the additional glycine has a dramatic effect on the structural preferences of the biologically important C-terminus, an effect brought about by the interaction with the lipid environment. These structural features are correlated to the biological activity at the bradykinin B2 receptor.     

Effect of conformation on the conversion of cyclo-(1,7)-Gly-Arg-Gly-Asp-Ser-Pro-Asp-Gly-OH to its cyclic imide degradation product.

The objective of this study was to explain the increased propensity for the conversion of cyclo-(1,7)-Gly-Arg-Gly-Asp-Ser-Pro-Asp-Gly-OH (1), a vitronectin-selective inhibitor, to its cyclic imide counterpart cyclo-(1,7)-Gly-Arg-Gly-Asu-Ser-Pro-Asp-Gly-OH (2). Therefore, we present the conformational analysis of peptides 1 and 2 by NMR and molecular dynamic simulations (MD). Several different NMR experiments, including COSY, COSY-Relay, HOHAHA, NOESY, ROESY, DQF-COSY and HMQC, were used to: (a) identify each proton in the peptides; (b) determine the sequential assignments; (c) determine the cis-trans isomerization of X-Pro peptide bond; and (d) measure the NH-HCalpha coupling constants. NOE- or ROE-constraints were used in the MD simulations and energy minimizations to determine the preferred conformations of cyclic peptides 1 and 2. Both cyclic peptides 1 and 2 have a stable solution conformation; MD simulations suggest that cyclic peptide 1 has a distorted type I beta-turn at Arg2-Gly3-Asp4-Ser5 and cyclic peptide 2 has a pseudo-type I beta-turn at Ser5-Pro6-Asp7-Gly1. A shift in position of the type I beta-turn at Arg2-Gly3-Asp4-Ser5 in peptide 1 to Ser5-Pro6-Asp7-Gly1 in peptide 2 occurs upon formation of the cyclic imide at the Asp4 residue. Although the secondary structure of cyclic peptide 1 is not conducive to succinimide formation, the reaction proceeds via neighbouring group catalysis by the Ser5 side chain. This mechanism is also supported by the intramolecular hydrogen bond network between the hydroxyl side chain and the backbone nitrogen of Ser5. Based on these results, the stability of Asp-containing peptides cannot be predicted by conformational analysis alone; the influence of anchimeric assistance by surrounding residues must also be considered.     

Unusual thionation of a cyclic hexapeptide. Conformational changes and dynamics.

One carbonyl oxygen of the cyclic hexapeptide cyclo(-Gly1-Pro2-Phe3-Val4-Phe5-Phe6-) (A) can be selectively exchanged with sulphur using Yokoyama's reagent. Surprisingly it was not the C=] of Gly1 but that of Phe5 which was substituted and cyclo(-Gly1-Pro2-Phe3-Val4-Phe5 psi [CS-NH]Phe6-) (B) was obtained. Thionation results in a conformational change of the peptide backbone although the C=O of Phe5 and the corresponding C=S are not involved in internal hydrogen bonds. Two isomers in slow exchange, containing a cis Gly1-Pro2 bond in a beta VIa-turn (minor) and a trans Gly-Pro bond in a beta II'-turn (major), were analyzed by restrained molecular dynamics in vacuo and in DMSO as well as using time dependent distance constraints. It is impossible to fit all experimental data to a static structure of each isomer. Interpreting the conflicting NOEs, local segment flexibility is found. MD simulations lead to a dynamic model for each structure with evidence of an equilibrium between a beta I- and beta II-turn about the Val4-Phe5 amide bond in both the cis and trans isomers. Additionally proton relaxation rates in the rotating frame (R1 rho) were measured to verify the assumption of this fast beta I/beta II equilibrium within each isomer. Significant contributions to R1 rho-rates from intramolecular motions were found for both isomers. Therefore it is possible to distinguish between at least four conformers interconverting on different time scales based on NMR data and MD refinement. This work shows that thionation is a useful modification of peptides for conformation-activity investigations.     

Solution conformations of bradykinin antagonists modified with Calpha-Calpha cyclized nonaromatic residues

The conformations of four BK antagonists, [D-Arg 0, Hyp3, Thi5, D-Phe7, Acc8]BK (1), Aaa[D-Arg 0, Hyp3, Thi5, D-Phe7, Acc8]BK (2), [D-Arg 0, Hyp3, Thi5, 8, Apc7]BK (3), and Aaa[D-Arg(0), Hyp(3), Thi(5, 8), Apc7]BK (4) were studied by using 2D NMR spectroscopy and MD simulations with time-averaged (TAV) restraints. According to the results of the NMR measurements, the BK antagonists contain 7-30% of minor conformation resulting from cis/trans isomerization of the peptide bonds preceding either Pro or Hyp residues. The major conformation of each peptide possesses all peptide bonds in trans configuration. Peptides modified with the Apc residue at position 7 (peptides 3 and 4) possess a higher percentage of minor isomer.Peptide 1 exhibits the strongest vasodepressor potency among the analogs studied and as a single one forms the betaII-turn in the 2-5 fragment, which is believed to be crucial for antagonistic activity. This peptide is also the most compact. The radius of gyration (Rg) amounts to 6.9 A and is by ca 1.5 A lower than that of the remaining analogs. With peptide 4, the ST-turn of type I within the Ser6-Thi8 fragment was found.     

Mimicking the membrane-mediated conformation of dynorphin A-(1-13)-peptide: circular dichroism and nuclear magnetic resonance studies in methanolic solution.

The structural requirements for the binding of dynorphin to the kappa-opioid receptor are of profound clinical interest in the search for a powerful nonaddictive analgesic. These requirements are thought to be met by the membrane-mediated conformation of the opioid peptide dynorphin A-(1-13)-peptide, Tyr1-Gly2-Gly3-Phe4-Leu5-Arg6-Arg7-Ile8-Arg9-Pro10- Lys11-Leu12-Lys13. Schwyzer has proposed an essentially alpha-helical membrane-mediated conformation of the 13 amino acid peptide [Schwyzer, R. (1986) Biochemistry 25, 4281-4286]. In the present study, circular dichroism (CD) studies on dynorphin A-(1-13)-peptide bound to an anionic phospholipid signified negligible helical content of the peptide. CD studies also demonstrated that the aqueous-membraneous interphase may be mimicked by methanol. The 500- and 620-MHz 1H nuclear magnetic resonance (NMR) spectra of dynorphin A-(1-13)-peptide in methanolic solution were sequence-specifically assigned with the aid of correlated spectroscopy (COSY), double-quantum filtered phase-sensitive COSY (DQF-COSY), relayed COSY (RELAY), and nuclear Overhauser enhancement spectroscopy (NOESY). 2-D CAMELSPIN/ROESY experiments indicated that at least the part of the molecule from Arg7 to Arg9 was in an extended or beta-strand conformation, which agreed with deuterium-exchange and temperature-dependence studies of the amide protons and analysis of the vicinal spin-spin coupling constants 3JHN alpha. The results clearly demonstrated the absence of extensive alpha-helix formation. chi 1 rotamer analysis of the 3J alpha beta demonstrated no preferred side-chain conformations.     

NMR and simulated annealing investigations of bradykinin in presence of polyphenols

Epidemiological studies have shown that the incidence of some cardiovascular degenerative diseases appears to be lower in populations with regular but moderate drinking of red wine rich in polyphenols. One of the most important properties of polyphenols is to form complexes with proteins. The linear nonapeptide hormone bradykinin (H-Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9-OH) is involved in a variety of physiological processes such as the cardiovascular processes. Thus, the goal of this work was to study the effects of tannins on the peptide structure by NMR investigations and molecular modeling. The results of these investigations show that in the presence of catechin, the peptide conformation is not affected and is in a random coil structure. On the contrary, the peptide structure is modified by the addition of dimeric proanthocyanidin B3 (catechin 4alpha-->8 catechin). The dimer leads to the formation of a large flexible turn between the 6-9 residues. Thus, the biological activities of bradykinin in the presence of polyphenols could be affected.     

Spatial structure of BAM-12P dodecapeptide and its analogues

Theoretical conformational analysis was used to study the spatial structure and conformational properties of the bovine adrenal medulla dodecapeptide BAM-12P (Tyr1-Gly2-Gly3-Phe4-Met5-Arg6-Arg7-Val8-Gly9-Arg10-Pro11-Glu12). Twenty-three low-energy conformations of the BAM-12P backbone were shown to represent the spatial structure of the peptide. The inverse structural problem was solved, and synthetic analogues of BAM-12P were proposed, the spatial structures of which correspond to a set of low-energy potentially physiologically active conformations of the natural dodecapeptide. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2005, vol. 31, no. 3; see also http://www.maik.ru.     

Synthesis and biological evaluation in vitro of a selective, high potency peptide agonist of human melanin-concentrating hormone action at human melanin-concentrating hormone receptor 1

Human melanin-concentrating hormone (hMCH) is a nonselective natural ligand for the human melanin-concentrating hormone receptors: hMCH-1R and hMCH-2R. Similarly, the smaller peptide encompassing the disulfide ring and Arg(6) of hMCH, Ac-Arg(6)-cyclo(S-S)(Cys(7)-Met(8)-Leu(9)-Gly(10)-Arg(11)-Val(12)-Tyr(13)-Arg(14)-Pro(15)-Cys(16))-NH(2), Ac-hMCH(6-16)-NH(2), binds to and activates equally well both human MCH receptors present in the brain. To separate the physiological functions of hMCH-1R from those of hMCH-2R, new potent and hMCH-1R selective agonists are necessary. In the present study, analogs of Ac-hMCH(6-16)-NH(2) were prepared and tested in binding and functional assays on cells expressing the MCH receptors. In these peptides, Arg in position 6 was replaced with various d-amino acids and/or Gly in position 10 was substituted with various L-amino acids. Several of the new compounds turned out to be potent agonists at hMCH-1R with improved selectivity over hMCH-2R. For example, peptide 26 with d-Arg in place of L-Arg in position 6 and Asn in place of Gly in position 10, Ac-dArg(6)-cyclo(S-S)(Cys(7)-Met(8)-Leu(9)-Asn(10)-Arg(11)-Val(12)-Tyr(13)-Arg(14)-Pro(15)-Cys(16))-NH(2), was a potent hMCH-1R agonist (IC(50) = 0.5 nm, EC(50) = 47 nm) with more than 200-fold selectivity with respect to hMCH-2R. Apparently, these structural changes in positions 6 and 10 results in peptide conformations that allow for efficient interactions with hMCH-1R but are unfavorable for molecular recognition at hMCH-2R.     

Spatial Structure of BAM-12P Dodecapeptide and Its Analogues

Theoretical conformational analysis was used to study the spatial structure and conformational properties of the bovine adrenal medulla dodecapeptide BAM-12P (Tyr1-Gly2-Gly3-Phe4-Met5-Arg6-Arg7-Val8-Gly9-Arg10-Pro11-Glu12). Twenty-three low-energy conformations of the BAM-12P backbone were shown to represent the spatial structure of the peptide. The inverse structural problem was solved, and synthetic analogues of BAM-12P were proposed, the spatial structures of which correspond to a set of low-energy potentially physiologically active conformations of the natural dodecapeptide.__________Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 3, 2005, pp. 245–250.Original Russian Text Copyright © 2005 by Akhmedov, Tagiev, Hasanov, Makhmudova.