Conformational analysis of two cyclic disulfide peptides

Complete nmr and CD studies of two cyclic tetrapeptides with disulfide bonds, Ac-L-Pen-L-Pro-D-Val-L-Cys-NH2 (1) and Ac-L-Cys-L-Pro-D-Val-L-Cys-NH2 (2) bonds have been carried out in different solvents to investigate the formation and stabilization of beta-turn structures and to determine the stereochemistry of the disulfide linkage. Both peptides have three-dimensional structures with a type II beta-turn, as derived from quantitative nuclear Overhauser effect data. The combined use of CD and nmr indicates that the dihedral angle of the disulfide bridge is different in the two peptides, although the chirality is maintained.     

Conformational heterogeneity of quinoxaline peptides in solution.

The conformational heterogeneity of several quinoxaline antibiotics, a class of naturally occurring quinoxaline peptides with antitumor properties, and their synthetic analogues was investigated in polar and nonpolar solvents by high performance liquid chromatography (HPLC) with uv photodiode array detection, uv-absorbance, low-temperature phosphorescence, and nmr techniques. Multiple peak formation and interconversion in the HPLC and 1H-nmr analysis of triostin A, its under-N-methylated synthetic analogues (des-N-tetramethyltriostin A [TANDEM] and [N-MeCys3, N-MeCys7]-TANDEM [MCTAN-DEM]), and echinomycin were examined as a function of temperature, solvent polarity, and residence time in solution prior to analysis. Slow interconversion between HPLC peaks, ascribed to the presence of multiple solution conformers, was exhibited by these peptides although at very different interconversion rates. Among the triostins, the rate of interconversion appeared to vary with the degree of N-methylation of the residues in the cyclic depsipeptide chain. Interconversion of the n and p conformers of triostin A in chloroform occurred on a chromatographic timescale (a few minutes with kn----p calculated to be 0.02 s-1 at 25 degrees C) while the solution conformers of TANDEM in methanol equilibrated very slowly to one preferred conformer over a period of several weeks at ambient temperature. MCTANDEM, a synthetic analogue of triostin A with an intermediate degree of N-methylation of the residues in the peptide ring, consisted of an equilibrium mixture of n and p conformers in methanol that interconverted on a chromatographic time scale. Two additional conformers of MCTANDEM developed within a few weeks' residence time in methanol at ambient temperature. Echinomycin was found to exist in methanol as an interconverting mixture of at least four minor conformers in addition to the major isoform (95% by peak area) of the peptide. The solution conformers of the quinoxaline peptides investigated in this report are most likely a consequence of hindered rotation about the N-methylated peptide bonds in the depsipeptide ring and/or intramolecular hydrogen bonding.     

XII. Conformational studies of histidine-containing peptides in solution

The spectroscopic properties (uv, CD, nmr) of histidine, glycylhistidine, histidylglycine, glycylhistidylglycine have been investigated in water and methanol in the temperature range 200–320 K in order to obtain information about their conformational equilibria. This analysis has been carried out for the different ionic forms of the compounds, in order to evaluate the influence of the ionization state of the carboxyl, histidyl, and amino groups on the rotamer distribution of the histidyl side chain (as evaluated from proton nmr analysis) and on the overall molecule (as judged from CD spectra). On the basis of certain approximations and from the temperature dependence of the proton nmr resonance, the thermodynamic parameters (ΔH° and ΔS°) characterizing the conformational equilibrium of the hystidyl side chain have been evaluated for the different structures and ionization states. Relatively large entropy differences between the rotamers are obtained in some cases. The data of the sidechain rotamer population, as determined by nmr, have been analytically correlated with the CD data, and in the case of hystidine and histidylglycine in basic solution, first-approximation values for the ellipticity of the single conformers have been evaluated. Finally, in the example of glycylhistidine and histidylglycine in basic solution, it is shown how the data obtained from the different experimental approaches (nmr and CD), as well as from theoretical energy calculations, converge to characterize the most stable conformation in solution.     

Stereochemical studies on cyclic peptides. Part X. Conformational analysis of hydrogen bonded cyclic pentapeptides.

Conformational aspects of 4 leads to 1 hydrogen bonded cyclic pentapeptides are considered in this paper from the point of view of "contact criteria" and potential energy calculations. Three types of such hydrogen bonded conformations, designated A1, A2 and B, are possible, involving some amount of strain on the bond angles. The energy of hydrogen bonded cyclopentaglycyl is somewhat less than that of the five-fold symmetrical conformation. The stereochemical feasibility of introducing L- and D-alanyl resudues in these structures has also been studied and the possible types for different sequences of alanyl residues have been determined. The results are discussed further in the light of the limited data available from crystal structure and nuclear magnetic resonance studies on cyclic pentapeptides.     

Backbone modifications in cyclic peptides. Conformational analysis of a cyclic pseudopentapeptide containing a thiomethylene ether amide bond replacement

NMR and X-ray crystallographic studies have shown that cyclic pentapeptides of the general structure cyclo(D-Xxx-Pro-Gly-Pro-Gly) possess beta- and gamma-turn intramolecular hydrogen bonds. As part of our continuing series surveying the compatibility of various amide bond replacements on peptide structure, we have synthesized cyclo(D-Phe-Pro psi[CH2S]Gly-Pro-Gly). The pseudopeptide was prepared by solid phase methods and cleaved from the resin by a new procedure involving phase transfer catalysis using K2CO3 and tetrabutylammonium hydrogen sulfate. Cyclization was carried out with the use of DPPA, HOBt, and DMAP to afford the product in 69% yield. The conformational behavior of the pseudopeptide was analyzed by 1H and 13C (1D and 2D) NMR techniques. The backbone modification replaced the amide bond that is involved in a gamma-turn intramolecular hydrogen bond in the all-amide structure. In CDCl3, the pseudopeptide adopted the same all-trans conformation as its parent, although the remaining beta-turn hydrogen bond was weaker according to delta delta/delta TNH measurements. In DMSO-d6, the all-trans conformer and a second conformer were observed in a ratio of 55:45. These conformers, which slowly interconverted on the NMR time scale, could be separately assigned; peaks due to chemical exchange were readily distinguishable by the ROESY technique as reported earlier by others. 13C and ROESY experiments suggested the minor conformer contained one cis amide bond at the Gly1-Pro2 position. Thus, both the location and type of amide surrogate are important determinants affecting the compatibility of the replacement with a particular conformational feature.     

Conformational and biochemical analysis of the cyclic peptides which modulate serine protease activity.

Prostate-specific antigen (PSA), a member of the kallikrein sub-group of the trypsin serine protease family, is a widely used marker for prostate cancer. Several sequences with specific binding to PSA have been identified by using phage display peptide libraries. The GST-fusion proteins of the characterized sequences have been shown to increase the enzyme activity of PSA to a synthetic substrate. The corresponding three cyclic synthetic analogues CVFTSNYAFC (A-1), CVFAHNYNYLVC (B-2) and CVAYCIEHHCWTC (C-4) have similar PSA promoting activity. Despite differences in the amino acid sequences, all three peptides bind to the same region of PSA. The conformation of the peptides was investigated by proton NMR spectroscopy. In addition, alanine replacement was used to characterize the prerequisites for binding. It is proposed that interactions with PSA are based on the aromatic and hydrophobic features of the amino acid side chains. Furthermore, it is suggested that peptides form beta-turn structures forced by cysteine bridges directing important aromatic side chains to the same side of the turn-structure.     

Conformational analysis of cyclic angiotensin II analogues

Summary Conformationally restricted cyclic analogues of angiotensin II (ANG II), Asp¹-Arg²-Val³-Tyr⁴-Val⁵-His⁶-Pro⁷-Phe⁸, with a link between positions 3 and 5 have considerable biological activity. It is proposed that the spatial arrangement of the pharmacophore groups of Tyr⁴, His⁶ and Phe⁸ side chains and the C-terminal carboxyl group in ANG II and active analogues is similar. Conformational analysis of ANG II and two cyclic analogues c[Sar¹, Lys³,Glu⁵]ANG II and c[Sar¹,Hcy³,Mpt⁵]ANG II was performed, and a geometrical comparison of the low-energy conformations of these compounds allowed one to propose a model of receptor-bound conformation in terms of the spatial arrangement of the pharmacophore groups. This model is characterised by the close spatial location of the His⁶-Phe⁸ side chains and the Tyr⁴ C-terminal carboxyl group and is stabilised by the electrostatic interaction of Arg² and the C-terminal carboxyl group.Abbreviations ANG II angiotensin II - Hcy homocysteine - Mpt trans-4-mercaptoproline     

Conformational analysis in solution of gastrin releasing peptide

Gastrin releasing peptide (GRP) is the first peptide isolated from porcine gastric and intestinal tissues and is homologous to the carboxyl terminus of bombesin (Bn) isolated from the skin of the frog Bombina bombina. It is a member of the Bn-like peptides, which are important in numerous biological and pathological processes. The Bn-like peptides show high sequence homology in their C-terminal regions, but they have different selectivity for their receptors. In particular, GRP selectively binds to the GRP receptor (GRPR). However, the molecular basis for this selectivity remains largely unknown. Here, we report the three-dimensional structure of GRP. Hopefully, it could be helpful in a better understanding of the binding selectivity between GRP and GRPR.     

Conformational analysis of human calcitonin in solution.

The solution conformation of human calcitonin in a mixture of 60% water and 40% trifluoroethanol has been determined by the combined use of 1H NMR spectroscopy and distance geometry calculations with a distributed computing technique. 1H NMR spectroscopy provided 195 distance constraints and 13 hydrogen bond constraints. The 20 best converged structures exhibit atomic rmsd of 0.43 A for the backbone atoms from the averaged coordinate position in the region of Asn3-Phe22. The conformation is characterized by a nearly amphiphilic alpha-helix domain that extends from Leu4 in the cyclic region to His20. There are no significant differences observed among the overall structures of a series of calcitonins obtained from ultimobranchial bodies, including those that possess 20- to 50-fold greater activity. Three aromatic amino acid residues, Tyr12, Phe16 and Phe19, form a hydrophobic surface of human calcitonin. Bulky side chains on the surface could interfere with the ligand-receptor interaction thereby causing its low activity, relative to those of other species.     

Conformational modulation of in vitro activity of cyclic RGD peptides via aziridine aldehyde-driven macrocyclization chemistry

Here, we demonstrate a conjugation strategy whereby cyclic RGD-containing macrocycles are prepared using aziridine aldehydes, isocyanides, and linear peptides, followed by conjugation to a cysteamine linker. Our method involves site-selective aziridine ring-opening with the nucleophilic sulfhydryl group of cysteamine. Fluorescein was then efficiently conjugated to the primary amine of cysteamine by NHS-chemistry. This strategy may be expanded to provide easy access to a wide variety of fluorescent dyes or radiometal chelators. Modeling studies showed that aziridine aldehyde cyclization chemistry stabilized the RGD motif into the required bioactive conformation and that this cyclization chemistry modulated the geometry of macrocycles of different residue lengths. In vitro studies showed that cPRGDA and cPRGDAA both selectively bound to α(V)β(3)-overexpressing U87 glioblastoma cells, and that cPRGDA had a better binding affinity compared to cPRGDAA. The improved binding affinity of cPRGDA was attributed to the fixed Pro-C(α)-Asp-C(α) distance surrounding the stabilized RGD motif in cPRGDA.     

Conformational analysis of the tetrapeptide Pro-D-Phe-Pro-Gly in aqueous solution

Conformational investigations of the tetrapeptide Pro-D-Phe-Pro-Gly in water solution were carried out by 1H and 13C NMR spectroscopy. The internal proline residue allows for the possibility of cis/trans isomerization about the D-Phe-Pro peptide bond resulting in two conformational isomers. The major isomer was identified as the trans isomer. The pH-dependence of the cis/trans equilibrium supports an additional stabilisation of the trans isomer by an intramolecular ionic interaction between the amino- and carboxy-terminus in the zwitterionic state. Based on 13C spin-lattice relaxation times (T1), different pyrrolidine ring conformations of Pro1 and Pro3 could be determined. By combination of several NMR data (vicinal coupling constants 3JN alpha, temperature dependence of the NH chemical shifts, differences in the chemical shifts between the beta and gamma carbons of the proline residues) and energy minimization calculations, a type II' beta-turn should contribute considerably to the overall structure of the trans isomer.     

Conformational mobility in cyclic oligopeptides

Analysis of two isomeric cyclic hexapeptides of composition (Asp, Arg, Gly₂, Pro, D -Pro) by a nuclear Overhauser effect constrained distance geometry conformation search yielded a narrowly defined backbone conformation for one and considerable ambiguity about the conformation in part of the other. Preliminary ¹³C relaxation studies of these peptides suggest that it is possible that this difference may correspond to a physical difference in internal mobility. In connection with this observation, other experimental evidence bearing on the backbone conformational mobility of cyclic oligopeptides with 4–10 residues, frequently considered to have well-defined backbones, is reviewed. Conformational heterogeneity involving rotation of a peptide bond plane relative to the overall ring plane is identified as a common phenomenon. Nuclear magnetic resonance line-shape studies at temperatures down to 200 K can detect backbone motions with activation free energy barriers down to about 10 kcal/mole, but conformational exchange with lower barriers, though detectable in other ways, will not be obvious from nmr spectra alone. © 1993 John Wiley & Sons, Inc.     

Mass spectrometric analysis of head-to-tail connected cyclic peptides

Tandem mass spectrometry is an extremely useful tool for high sensitive sequence identification of peptides. In the case of cyclic peptides fragmentation can easily be performed for sequence analysis. However, analysis is usually tedious due to the lack of a defined beginning and end of the sequence. Since cyclic peptides are a highly interesting class of compounds especially for the pharmaceutical industry, ways have to be found to identify their strictures. In this work we demonstrate how software and dedicated analytical strategies can be used for detailed analysis of these substances.     

Conformational aspects of N-glycosylation of proteins. Studies with linear and cyclic peptides as probes

Conformational aspects of N-glycosylation of glycoproteins have been studied by using a series of peptides which contained, in addition to the `marker sequence' Asn-Gly-Thr, two cysteine residues in various positions of the peptide chain. The presence of two cysteines permitted a partial fixation of the above triplet sequence in cyclic structures of various size by intramolecular disulphide bond formation. Comparison of the glycosyl acceptor properties of the linear peptides and their corresponding cyclic analogues allows the following statements. The considerably lower acceptor capabilities of the cyclic derivatives indicate that the restriction of rotational degrees of freedom imposed by disulphide bonding results in a conformation which hinders a favourable interaction of the peptide substrate with the N-glycosyltransferase. On the other hand, the glycosylation rate of linear peptides increases with increasing chain length, suggesting that the amino acids on both the N- and C-terminal side of the `marker sequence' may contribute to a considerable extent to the induction of an `active' conformation. Realization of a potential sugar attachment site requires a hydrogen bond interaction within the `marker sequence' between the oxygen of threonine (serine) as the hydrogen bond acceptor and the β-amide of asparagine as the donor [Bause & Legler (1981) Biochem. J. 195, 639–644]. This interaction is obviously facilitated when the peptide chain can adopt a conformation which resembles a β-turn or other loop structure. The available experimental and statistical data are discussed in terms of possible structural features for N-glycosylation, with the aid of space-filling models.