Nmr studies of the molecular conformations in the linear oligopeptides H-(L-Ala)n-L-Pro-OH

The molecular conformations of the linear oligopeptides H-(L -Ala)_n-L -Pro-OH, with n = 1,2 and 3, have been investigated. ¹³C nmr observation of the equilibrium between the cis and trans forms of the Ala-Pro peptide bond indicated the occurrence of nonrandom conformations in solutions of these flexible peptides. The formation of the nonrandom species containing the cis form of the Ala-Pro bond was found to depend on the deprotonation of the carboxylic acid group of proline, the solvent, and the ionic strength in aqueous solution. The influence of intramolecular hydrogen bonding on the relative conformational energies of the species containing the cis and trans Ala-Pro peptide bond was studied by comparison of the peptides H-(Ala)_n-Pro-OH with analogous molecules where hydrogen bond formation was excluded by the covalent structure. In earlier work a hydrogen bond between the protonated terminal carboxylic acid group and the carbonyl oxygen of the penultimate amino acid residue had been suggested to stabilize conformations including trans proline. For the systems described here this hypothesis can be ruled out, since the cis:trans ratio is identical for molecules with methyl ester protected and free protonated terminal carboxylic acid groups of proline. Direct evidence for hydrogen bond formation between the deprotonated terminal carboxylic acid group and the amide proton of the penultimate amino acid residue in the molecular species containing cis proline was obtained from ¹H nmr studies. However, the cis:trans ratio of the Ala-Pro bond was not affected by N-methylation of the penultimate amino acid residue, which prevents formation of this hydrogen bond. Overall the experimental observations lead to the conclusion that the relative energies of the peptide conformations including cis or trans proline are mainly determined by intramolecular electrostatic interactions, whereas in the molecules considered, intramolecular hydrogen bonding is a consequence of specific peptide backbone conformations rather than a cause for the occurrence of energetically favored species. Independent support for this conclusion was obtained from model consideration which indicated that electrostatic interactions between the terminal carboxylic acid group and the carbonyl oxygen of the penultimate amino acid residue could indeed account for the observed relative conformational energies of the species containing cis and trans proline, respectively.     

Characterization of triple-helical conformations and melting analyses of synthetic collagen-like peptides by reversed-phase HPLC

There is a confusion in the application of circular dichroism (CD) spectroscopy in analyzing collagen's structure for the overlapping of the spectral shapes and positions of the collagen triple helix and poly(proline-II)-like structure. The unique repetitive sequence of the collagen triple helix is susceptible to misalignment during the spontaneous assembly. Such misaligned structures are usually difficult to be characterized by CD or NMR spectroscopy. Here, RP-HPLC was developed as a conformational characterization technique for synthetic collagen-like peptides based on the different hydrophobicities exhibited by the triple-helical and unassembled peptides. RP-HPLC was also used to study thermal transitions and to measure melting point temperatures (Tm) of the collagen-like peptides.     

Melanostatin conformations in solution.

The conformations of melanostatin have been studied experimentally using CD spectroscopy and via calculations. In aqueous solution and 2,2,2-trifluoroethanol (TFE) there is no evidence that monomers of the tripeptide exist in an ordered (β-bend) structure. In water and TFE solutions (3–6 × 10^?4M) the neutral molecules aggregate very slowly, taking about 3 days to attain equilibrium at room temperature. At equivalent concentrations in TFE, although not in water, the cationic molecules also slowly aggregate, although to a lesser extent. Calculations using rotational isomeric state theory give the most probable unperturbed end-to-end distance of the molecule at 9.3 ± 0.1 Å and indicate that a vast majority of the molecules exist in some extended conformation, end-to-end distance ≥6 Å. Only 0.4% of the molecules are calculated to have O…?H separations compatible with a β-bend structure. An intramolecular hydrogen bond must have an energy at least 2 kcal/mol lower than that of an intermolecular hydrogen bond to solvent if a β-bend is to be experimentally observable.     

Nmr studies on linear homo-oligopeptides: A perspective view

The use of high-resolution nmr to determine the structure of linear homo-oligopeptides in solution is described. Complete assignments of NH and α-CH resonances were elucidated based upon a guest–host series of compounds and selective α-deuteration of residues in the chain. The conformations for oligomethionines and oligoglutamates in dimethylsulfoxide, chloroform, and trifluoroethanol are discussed, and molecular models are described. Recent studies of L -glutamate peptides attached to polyoxyethylene are also included. These peptide–polyoxyethylene conjugates are soluble in a broad range of solvents, such as dimethyl-sulfoxide, chloroform, trifluoroethanol, and water. Preliminary conclusions are drawn concerning the effects of amine terminal end groups and the nature of the solvent on the conformations of these peptide derivatives.     

Contrasting solution conformations of peptides containing α,α-dialkylated residues with linear and cyclic side chains

The conformational properties of α,α-dialkylated amino acid residues possessing acyclic (diethylglycine, Deg: di-n-propylglycine, Dpg; di-n-butylglycine, Dbg) and cyclic (1-amino-cycloalkane-1-carboxylic acid, Ac_nc) side chains have been compared in solution. The five peptides studied by nmr and CD spectroscopy are Boc-Ala-Xxx-Ala-OMe, where Xxx = Deg(I). Dpg (II), Dbg (III), Ac₆c (IV), and Ac₇c (V). Delineation of solvent-shielded NH groups have been achieved by solvent and temperature dependence of NH chemical shifts in CDCl₃ and (CD₃)₂SO and by paramagnetic radical induced line broadening in pepiide III. In the Dxg peptides the order of solvent exposure of NH groups is Ala(1) > Ala(3) > Dxg(2), whereas in the Ac_nc peptides the order of solvent exposure of NH groups is Ala(1) > Ac_nc(2) > Ala(3). The nmr results suggest that Ac_nc peptides adopt folded β-turn conformations with Ala(1) and Ac_nc(2) occupying i + 1 and i + 2 positions. In contrast, the Dxg peptides favor extended C₅ conformations. The conformational differences in the two series are clearly borne out in CD studies. The solution conformations of peptides I-III are distinctly different from the β-turn structure observed in crystals. Low temperature nmr spectra recorded immediately after dissolution of crystals of peptide II provide evidence for a structural transition. Introduction of an additional hydrogen-bonding function in Boc-Ala-Dpg-Ala-NHMe (VI) results in a stabilization of a consecutive β-turn or incipient 3₁₀-helix in solution. © 1995 John Wiley & Sons, Inc.     

Bioactive conformation of linear peptides in solution: An elusive goal?

Bioactive peptides of natural origin have, in general, short linear sequences, and are characterized by a large conformational flexibility. It is very difficult to study their conformation in solution since they exist, almost invariably, as a complex mixture of numerous conformers, most of which are extended. The so-called bioactive conformation may be one of them, although the solvents used in solution studies often have properties drastically different from those of the biological system in which the peptide acts. There is, however, no simple way of identifying the bioactive conformation amid the many existing conformers. It is possible to approach a solution to this problem using two distinct strategies: (a) Limiting the conformational freedom of the peptide, e.g., by increasing the viscosity of the solution and decreasing the temperature, in the assumption that the bioactive conformation is, even slightly, more stable than the others. (b) Trying to mimic in solution the physicochemical features of the more reliable receptor models. These two approaches will be illustrated with examples taken mainly from opioid peptides.     

Solution conformations of some azetidine cyclic peptides

The ¹H-nmr spectra (270 MHz) of cyclic di- and tri-L -azatidine-2-carboxylic acid [cy-clo(L -Aze)₂ and cyclo(L -Aze)³] were determined in CDCl₃ and D₂O and computer simulated. The spectral results were compared with those obtained with cyclo (L -Pro)₂ and cyclo (L, -Pro)₃. In CDCl₃ and D₂O solution, the four membered ring of cyclo (L -Aze)₂ is puckered with the α-proton in a pseudo-axial position, and the ? angle is smaller in absolute value than ?60°, as found for cyclo (L -Pro)_2,. The puckering of the four-membered ring of cyclo(L, -Aze)₃ in CDCl₃ has the α-proton in a pseudo–equatorial position and ? angle larger in absolute value than ?60°, in agreement with cyclo(L -Pro)₃. In D₂O, cyclo(L -Aze)₃ was found to interconvert rapidly between different conformers. In the azetidine cyclic peptides studied, the range of values found for the ? angles was smaller than in the related proline cyclic peptides, indicating greater rigidity in the four-membered ring.     

Nuclear Overhauser effects in aqueous solution as dynamic probes in short linear peptides

The possibility of obtaining interresidue NOEs from short linear peptides in aqueous solution has been investigated from an experimental point of view using peptides of various lengths (namely GGRA, LHRH and RNase S-peptide). It is shown that, provided that long (approximately 800 ms) NOESY mixing times are used, complete sets of sequential alpha N NOEs are obtainable. From the intensities and signs of the observed NOEs, the relative mobilities of different parts of the polypeptide chain can be determined.     

Virtual and solution conformations of oligosaccharides

The possibility that observed nuclear Overhauser enhancements and bulk longitudinal relaxation times, parameters measured by 1H NMR and often employed in determining the preferred solution conformation of biologically important molecules, are the result of averaging over many conformational states is quantitatively evaluated. Of particular interest was to ascertain whether certain 1H NMR determined conformations are "virtual" in nature; i.e., the fraction of the population of molecules actually found at any time within the subset of conformational space defined as the "solution conformation" is vanishingly small. A statistical mechanics approach was utilized to calculate an ensemble average relaxation matrix from which (NOE)'s and (T1)'s are calculated. Model glycosidic linkages in four oligosaccharides were studied. The solution conformation at any glycosidic linkage is properly represented by a normalized, Boltzmann distribution of conformers generated from an appropriate potential energy surface. The nature of the resultant population distributions is such that 50% of the molecular population is found within 1% of available microstates, while 99% of the molecular population occupies about 10% of the ensemble microstates, a number roughly equal to that sterically allowed. From this analysis we conclude that in many cases quantitative interpretation of NMR relaxation data, which attempts to define a single set of allowable torsion angle values consistent with the observed data, will lead to solution conformations that are either virtual or reflect torsion angle values possessed by a minority of the molecular population. On the other hand, calculation of ensemble average NMR relaxation data yields values in agreement with experimental results. Observed values of NMR relaxation data are the result of the complex interdependence of the population distribution and NOE (or T1) surfaces in conformational space. In conformational analyses, NMR data can therefore be used to test different population distributions calculated from empirical potential energy functions.     

Proton magnetic resonance and model peptides conformations

Derivatives and peptides of β-nitrobenzyl-L -aspartates were studied with high-field nmr. Differences were observed between the chemical shifts of protons located near the extremity of the principal chain as a function of the terminal group. These differences are explained by conformational calculations which exclude the existence of an hydrogen bond and demonstrate the influence of the aromatic ring position on the protons of the main chain. Both nmr experiments and conformational analysis indicate that conformations are nearly the same for ortho, meta, and para nitro substitution. These conclusions are in good agreement with Karplus relationship applied to the α and β protons.     

Nonstereogenic alpha-aminoisobutyryl-glycyl dipeptidyl unit nucleates type I' beta-turn in linear peptides in aqueous solution

The use of alpha,alpha-disubstituted amino acids represents a valuable strategy to exercise conformational control in peptides. Incorporation of the nonstereogenic alpha-aminoisobutyryl-glycyl (Aib-Gly) dipeptidyl sequence into i+1 and i+2 positions of an acyclic peptide sequence, originally designed and investigated by Gellman and coworkers, [H-Arg-Tyr-Val-Glu-Val-Yyy-Xxx-Orn-Lys-Ile-Leu-Gln-NH2] nucleates a stable [2:4] left-handed type I' beta-turn in water. NMR spectra show that this newly designed beta-hairpin does not aggregate in water up to a concentration of approximately 1 mM, and that its backbone conformation is superimposable on corresponding hairpins containing the DPro-Gly (literature) and Aib-DAla (this work) sequences. The Aib-Gly turn-inducer sequence eliminates complications because of cis-trans isomerization of Zzz-Pro bonds, and constitutes an attractive alternative to the proteogenic Asn-Gly and nonproteogenic DPro-Gly motifs previously suggested as turn-inducer sequences. These design principles could be exploited to prepare water-soluble beta-hairpin peptides with robust structures and novel function.     

Stereochemistry of alpha-aminoisobutyric acid peptides in solution: helical conformations of protected decapeptides with repeating Aib-L-Ala and Aib-L-Val sequences

The decapeptides Boc-(Aib-L -Ala)₅-OMe and Boc-(Aib-L -Val)₅-OMe have been studied by 270-MHz ¹H-nmr in CDCl₃ and (CD₃)₂SO solutions. Intramolecular hydrogen-bonded NH groups have been delineated using the temperature and solvent dependence of the NH chemical shifts and differential broadening of the NH resonances, induced by addition of a nitroxide radical. Both peptides have eight solvent-shielded NH groups, suggesting that 3₁₀-helical conformations are maintained in the two solvents. In alternating Aib-X sequences, the Aib residues appear to play a dominant role in determining the preferred conformations, overriding the intrinsic stereochemical preferences of the X residues.     

Predicting the conformations of peptides and proteins in early evolution

Considering that short, mainly heterochiral, polypeptides with a high glycine content are expected to have played a prominent role in evolution at the earliest stage of life before nucleic acids were available, we review recent knowledge about polypeptide three-dimensional structure to predict the types of conformations they would have adopted. The possible existence of such structures at this time leads to a consideration of their functional significance, and the consequences for the course of evolution. This article was reviewed by Bill Martin, Eugene Koonin and Nick Grishin.