Studies of peptide conformation: Backbone folding of tetrapeptide derivatives in methanol and water

Derivatives of tetrapeptide sequences considered likely to form β-turns were investigated by the study of their proton magnetic resonances in methanol and in water. Differential broadening of N—H resonances by an added nitroxyl was used to indicate the presence of the sequestered N—H proton expected in β-turn conformations. Transfer of magnetic saturation from solvent water protons to N—H protons was also examined. The evidence is consistent with significant contributions by β-turn-like backbones to the conformational averages in methanol of the sequences Gly-L -Pro-D -Val-Gly, D (or L )-Val-L -Pro-Gly-Gly, and Gly-L -Pro-L -Asn-Gly, but not the sequence Gly-D -Ala-L -Val-Gly. It is suggested that a Type I turn, Likely in Gly-L -Pro-L -Asn-Gly derivatives, is characterized by sequestered N—H protons of both the third and fourth residues. For all of the peptide derivatives, save possibly Ac-L -Val-L -Pro-Gly-Gly-NHNH₂, contributions from folded structures in water are not detectable by line-broadening experiments. However, the transfer of saturation experiments may be interpreted as indicating some degree of chain folding in water.     

β-Alanine containing cyclic peptides with turned structure: The “pseudo type II β-turn.” VI

In the present paper we describe the synthesis, purification, single crystal x-ray analysis, and nmr solution characterization, combined with restrained molecular dynamic simulations, of the cyclic hexapeptide cyclo-(L -Pro-L -Phe-β-Ala)₂. The peptide was synthesized by classical solution methods and the cyclization of the free hexapeptide was accomplished in good yields in diluted methylene chloride solution using N,N-dicyclohexyl-carbodiimide. The compound crystallizes in the monoclinic space group P2₁ from methanol-dichloro-methane solution. The two identical halves of the molecule adopt in the solid state two different conformations. One β-Ala-L -Pro peptide bond is trans, while the second is cis. The molecule is present in dimethylsulfoxide d₆ solutions as a mixture of conformational families. One of these corresponds to a C₂ symmetrical molecule with both β-Ala-Pro cis peptide bonds, while the second major conformation is very similar to that observed in the solid state. All Pro-Phe segments, both in the solid state and the symmetrical and unsym-metrical solution conformations, display ?,ψ angles close to that of position i + 1 and i + 2 of type II β-turns. In addition, the segments preceeded by a trans β-Ala-Pro peptide bond are characterized by a typical i ← i + 3 hydrogen bond, which is absent in the conformer containing a cis β-Ala-Pro peptide bond. The latter conformation corresponds to a new structural domain we define as the “pseudo type II β-turn.” © 1994 John Wiley & Sons, Inc.     

Steric effects of cis-trans isomerism on neighboring residues in proline oligopeptides: A 13C-nmr study of conformational heterogeneity in linear tripeptides

A series of proline-containing linear oligopeptides (4 dipeptides and 15 tripeptides) were synthesized and examined in aqueous and nonaqueous solutions using ¹³C-nmr spectroscopy. Spectra of linear tripeptides showing cis-trans isomerism about the X-Pro bond (X = Pro, Gly, and Ala) also show neighboring effects on the chemical shifts of residues both preceding and following the prolyl moiety. The extent of cis-trans isomerism observed about the X-Pro peptide bond correlates not only with the nature of X, but also depends on the size of the residue following proline; the larger substituents favor an increase in cis content about the X-Pro bond.     

Conformational energy studies of linear dipeptides H-X-L-Pro-OH

Empirical conformational energy calculations with the use of ECEPP energy functions have been carried out for linear dipeptides H-X-L -Pro-OH, with X = Gly, L -Ala, D -Ala, L -Leu, D -Leu, L -Phe, and D -Phe, in different states of protonation of the end groups. The results of these calculations are compared with the previously reported experimental equilibrium populations for the cis and trans isomers of the X-Pro bond in the different species. For all the protonation states of the seven dipeptides, the calculated nonbonded interactions and the conformational entropy term lead to a preference of the trans forms over the cis isomers by at least 1 kcal/mol. The electrostatic interactions stabilize the cis conformations in all species except the cationic forms of the D ,L -peptides, and it could further be shown that only the carbonyl group of X and the two end groups contribute significantly to the total electrostatic energy. One of the principal results of the experimental studies, i.e., the occurrence of 5–15% cis-proline in all the peptides with an uncharged C-terminus, was corroborated by our investigation of the cationic species. A detailed assessment of the electrostatic contribution to the total energy of the different conformations of H-Gly-L -Pro-OH indicates that the standard ECEPP parameters tend to overestimate the electrostatic interactions in aqueous solutions of the X-Pro dipeptides.     

Cyclo(D-Pro-L-Pro-D-Pro-L-Pro): Structural properties and cis/trans isomerization of the cyclotetrapeptide backbone

Combinations of L - and D -proline residues are useful compounds for finding new structures and properties of cyclic peptides. This is demonstrated with one striking example, the cyclic tetrapeptide c(D -Pro-L -Pro-D -Pro-L -Pro). For this molecule composed of strictly alternating D - and L -configurated residues, a highly symmetrical structure is expected, which should be an optically inactive meso-form. Cyclization of the enantiomeric pure linear precursor D -Pro-L -Pro-D -Pro-L -Pro, however, yields a racemic mixture of two enantiomeric cyclotetrapeptides, both with twofold symmetry and a cis–trans–cis–trans sequence of the peptide bonds. Remarkably, this formation of a racemate was not caused by racemization, but by cis/trans isomerization of all peptide bonds in the ring. This process may occur in the linear precursor during the ring formation (cyclization of conformers with trans–cis–trans or cis–trans–cis arrangement of the amide bonds) as well as in the enantiomeric pure cyclic tetrapeptide at higher temperature. In the latter case, an all-cis structure should exist as the intermediate, which can form a cis–trans–cis–trans sequence in two equivalent ways, leading finally to two enantiomeric cyclotetrapeptides. In the first one, the cis peptide bonds are attributed to the L -residues and the trans peptide bonds to the D -residues; in the second one, the cis bonds belong to the D and the trans bonds to the L -residues. The mixture of these two enantiomers does not crystallize in the racemic form, but in enantiomeric pure separate crystals. The structural properties could be proved by ¹H- and ¹³C-nmr spectroscopy and x-ray analysis. The cis/trans isomerization process was confirmed by optical rotation measurements and CD spectroscopy, as well as DREIDING model studies. Calorimetric measurements in the solid state suggest the existence of the expected all-cis intermediate. The backbone conformation of the 12-membered medium-sized ring shows only slight deviations—up to 6° —from the planarity of the peptide bonds. On the other hand, the four pyrrolidine rings show different types of puckering of the C_γ or the C_β atoms.     

Conformational properties of Pro-Pro sequences. I. Crystal structures of two dipeptides with L-Pro-L-Pro and L-Pro-D-Pro sequences

The crystal structures of Bu^tCO-L -Pro-L -Pro-NHMe, H₂O (1: monoclinic; P2₁; a = 6.662, b = 11.067, c = 12.205 Å; β = 96.28°) and Bu^tCO-L -Pro-D -Pro-NHMe (2: monoclinic; P2₁; a = 10.770, b = 15.039, c = 11.325 Å; β = 110.00°) have been solved by x-ray diffraction. Structure 1 accommodates an open disposition with intermolecular interactions involving the water molecule, while 2 is βII-folded by an intramolecular i + 3 → i hydrogen bond. In both derivatives, small thermal parameters are indicative of fairly fixed conformations for the proline rings. Comparison between conformations of either isolated or adjacent L -Pro residues in the crystal structures of unstrained oligopeptides shows that the conformational properties of L -Pro-L -Pro sequences are probably a simple combination of those found for isolated L -Pro residues.     

13C- and 1H-nmr evidence for all-cis peptide bonds in cyclic tetrapeptide cyclo(L-Pro-Sar)2

Conformations of the cyclic tetrapeptide cyclo(L -Pro-Sar)₂ in solution were studied by ¹H- and ¹³C-nmr spectrometry and model building. The nmr data provide definite evidence that this cyclic peptide exists chiefly in two conformations, namely, a C₂-symmetric conformation and an asymmetric structure. The former was demonstrated to be predominant in polar solvents (100% in Me₂SO-d₆). This structure contains all cis-peptide bond linkages and all trans′ Pro C^α?CO bonds. It represents the first cyclic tetrapeptide in which all four peptide bonds have been found in the cis-conformation. As the polarity of the solvent decreases, the population of C₂-symmetric conformers decreases (88% in CD₃CN and 65% in CDCl₃). At the same time, a minor asymmetric conformer, characterized by cis-cis-cis-trans peptide bond sequences (two cis Sar-Pro bonds, one cis Pro-Sar bond, and one trans Pro-Sar bond), is seen to increase (9% in CD₃CN and 30% in CDCl₃). A proposed predominant conformation in solution for cyclo(L -Pro-Sar)₂ was compared with a crystal structure, as reported in an accompanying paper. Both structures show striking overall similarities.     

A 13C spin-lattice relaxation study of dipeptides containing glycine and proline: mobility of the cyclic proline side chain.

Molecular dynamics of the cyclic dipeptides cyclo(Gly-L -Pro), cyclo-(L-Pro-L -Pro), and cyclo(L-Pro-D-Pro) and the linear dipeptides L-Pro-Gly and cis and trans Gly-L -Pro were studied in neutral aqueous solution by ¹³C nuclear magnetic resonance. Spinlattice relaxation times (T₁) were determined for each individual carbon atom. The correlation times, τ, were derived from a semiquantitative analysis of the T₁ data. The correlation times of the proline ring carbons, β, γ, and δ suggest that the cyclic dipeptides have more restriction of conformational freedom in the proline ring than the linear dipeptides. This effect is most pronounced on the γ carbon.     

Structural investigation of poly-L,D-proline, a synthetic ion channel across bilayer membranes: crystal structure and molecular conformation of two tetra-D,L-proline derivatives

The crystal structures and molecular conformations of two tetraproline derivatives with alternating configurations Boc(D -Pro,L -Pro)₂OH and Boc(D -Pro,L -Pro)₂OCH₃ are investigated in connection with the ability of the homologous polymer to selectively increase (as an ion channel) the ion permeability across bilayer membranes. Both tetramers are characterized by the cis-trans alternating conformation of the peptide bonds, which formally transforms in a turn of the poly-D ,L -proline channel after a cis-trans change of the central peptide residue.     

Solvent and side-chain contributions to the two-cis ⇄ all-trans equilibria of cyclic hexapeptides,cyclo(Xxx-Pro-D-Yyy)2

Cyclic hexapeptides of the type cyclo(L -Xxx-L -Pro-D -Yyy)₂ or cyclo(L -Xxx-L -Pro-Gly)₂ exist in solution predominantly in two forms of C₂ average symmetry, one with all-trans peptide bonds and generally well-established conformation, and another with both Xxx-Pro peptide bonds cis. We have been measuring the thermodynamic parameters of this equilibrium using carbon and proton nmr spectroscopy. Data have been obtained for peptides in which Yyy = Gly, D -Ala, or D -Phe, and Xxx = Gly, L -Ala, L -Leu, and L -Val. In a given solvent, stability of the all-trans form decreases (ΔG⁰ increases) as Xxx is changed through the series Gly, L -Ala-, L -Leu, and L -Val, consistent with expected increasing repulsion between the Xxx side chain and the proline δ methylene across the trnas Xxx-Pro bond. Also, for a given set of side chains, the stability of the all-trnas form increases as the polarity of the solvent decreases, consistent with models in which all C?O and N? H groups are accessible for solvation in the two-cis form, but two C?O and two N? H groups are somewhat sequestered in the all-trans form. With the available data it is not possible to identify pure intramolecular (solvent-independent) or pure peptide-bond solvation (side chain-independent) terms in ΔH° or ΔS°, although trends are discernible.     

Conformations of oligoprolines with different configurational sequences and their association complexes with alkali and alkali-earth ions

To clarify the possible molecular mechanism of cation unit conductance of poly(D ,L -proline) across lipidic membranes, the structure and conformation of tetraproline derivatives with different configurational sequences in solid state, as well as in solution and in the presence of alkali and alkali-earth ions, were investigated using x-ray analysis, CD, and nmr spectroscopy. The tetraproline derivatives Boc(D -Pro-L -Pro-L -Pro-D -Pro)OBg and Boc(L -Pro)₄OBg show very different conformational versatilities in solutions as well as different propensities to form complexes with Ca²⁺ ion. This is interpreted, based on previous evidence, as due to different abilities to form ion complexing cavities. © 1998 John Wiley & Sons, Inc. Biopoly 45: 257–267, 1998     

The role of water in the crystal structure of N-acetyl-L-4-hydroxyproline

The crystal structure of N-acetyl-L -4-hydroxyproline (Hyp) was determined by direct methods. (The crystal is orthorhombic with the space group P2₁2₁2₁.) The acetyl group is in the trans conformation and the pyrrolidine ring puckers at C^γ (C^sC^γ envelope), as in most Hyp residues. According to the rotation angle ψ = ?30°, the N-acetyl-L -4Hyp has the same conformation as an α-helix of prolyl residues. The crystal packing is stabilized by hydrogen bonds between three different molecules and the same molecule of water. One of the water bridges involves the carbonyl of the N-acetyl group of one molecule and the hydrogen atom of the 4-OH group of another. Such an arrangement has been proposed to explain the high stability of (Gly-L -Pro-L -4Hyp)_n. A second bridge involves the two hydrogens of the water molecule and the carbonyl groups of two neighbouring molecules, as already proposed in a dihydrated model of collagen. These experimental features, which are discussed in relation to the different models of collagen, allow us to propose an hypothetical arrangement for the water molecule which is strongly retained in the triple helix of (Gly-L -Pro-L -4Hyp)_n.     

The effects of isolated N-methylated residues on the conformational characteristics of polypeptides

Conformational energies have been estimated for the tripeptide fragments L -Ala-N-methyl-L -Ala-L -Ala, L -Ala-L -Ala-N-methyl-L -Ala, L -Ala-Sar-L -Ala, and L -Ala-Gly-N-methyl-L -Ala. The peptide bonds connecting L -Ala and Gly with N-methyl-L -Ala and L -Ala with Sar were permitted to adopt the planar cis as well as the usual trans conformation. Contour maps of the conformational energies of the central residue in these tripeptide fragments are presented and compared to the conformational energy maps previously calculated for unmethylated L -Ala and Gly surrounded by residues which are also unmethylated. In generl it is observed that L -Ala and Gly residues that are either N-methylated in their conformational freedom relative to the same residues in an unmethylated polypeptide chain.     

Determination of the rates and barriers to conformational isomerization in the dipeptide L-pro-L-4hyp by direct 13C nmr thermal equilibration

The ¹³C nmr equilibration method lends itself as a tool for study of conformational rate processes involving aqueous media in conjunction with high activation barriers. This method is applied for measurement of kinetic and thermodynamic parameters of isomerism in the dipeptide L -Pro-L -4Hyp. The activation barrier for cis ? trans interconversion (ω 0° → 180°) is determined, ΔG^≠ = 22.3 kcal/mol. From low-temperature study, an upper limit ΔG^≠ < 9.7 kcal/mol is evaluated for cis′ ? trans′ rotation (ψ ?40° → 160°). These data are compared with computed values found in literature. The results are discussed in connection with the helix–coil transition of collagen involving Gly-L -Pro-L -4Hyp as nucleation sites.     

Cation binding cyclic peptides composed of imino acid residues

Cyclo(L -Pro-Sar)_n (n = 2–4) with moderate flexibility and hydrophobicity of molecular structure was synthesized, and the characteristics of these cyclic peptides and their metal complexes in acetonitrile were investigated in connection with the residual properties using ¹³C-nmr measurements. The cyclic tetrapeptide cyclo(L -Pro-Sar)₂ showed a sterically hindered phenomenon in acetonitrile in which the amide backbone adopted a cis-trans-cis-trans sequence. The cyclic hexapeptide cyclo(L -Pro-Sar)₃ existed as a mixture of several conformers whose interconversion is slow on the nmr time scale, including cis-cis-trans and/or cis-trans-trans arrangement of the Sar-Pro bond. Finally, it was demonstrated that the cyclic octapeptide cyclo(L -Pro-Sar)₄ behaved as a mixture of multiple conformers which allowed for cis-trans isomerism about the Pro-Sar peptide bond, of which 20–30% had the all-cis Sar-Pro bond isomer and the remaining 70–80% had one (or more) cis Sar-Pro bond isomer. ¹³C-nmr spectra also demonstrated that cyclo(L -Pro-Sar)_n (n = 3,4) formed a 1:1 ion complex whose conformation was characterized by an all-trans peptide bond in the presence of excess metal salt. Cation binding studies, using CD measurements, established that the ion selectivity of cyclo(L -Pro-Sar)₄ in acetonitrile decreased in the order, Ba²⁺ > Ca²⁺ > Na⁺ > Mg²⁺ > Li⁺.     

Far-infrared spectra of sequential copolymers of amino acids with alkyl group side chains

Far-infrared spectra were measured for the sequential copolymers of amino acids with alkyl group side chains. The analysis of the spectra showed that (L -Ala-L -Ala-Gly)_n, (L -Ala-Gly)_n, (L -Ala-Gly-Gly)_n, (L -Val-L -Ala-L -Ala)_n, and (L -Val-L -Ala)_n, have the antiparallel pleated sheet structures and that the backbone conformations of (L -Val-L -Val-L -Ala)_n and (L -Val-L -Val-Gly)_n are the same as that of poly-L -valine. The far-infrared bands characteristic of the antiparallel pleated sheet structure were assigned on the basis of the result of the normal coordinate analysis of poly-L -alanine with this structure. The intersheet and interchain spacings of the sequential copolymers with the antiparallel pleated sheet structure were determined from the x-ray powder-diffraction patterns of these samples.     

β-Alanine containing peptides: γ-Turns in cyclotetrapeptides

In the present paper we describe the synthesis, purification, single-crystal x-ray analysis, solution conformational characterization, and conformational energy calculations of the cyclic tetrapeptide cyclo- (β-Ala-L -Pro-β-Ala-L -Val). The peptide was synthesized by classical solution methods and the cyclization of the free tetrapeptide was accomplished in good yields in diluted methylene chloride solution using N,N-dicyclohexyl-carbodiimide. The compound crystallizes in the monoclinic space group P2₁ from ethanol with two independent molecules in the unit cell. All peptide bonds are trans. The nmr molecular conformation in the acetonitrile solution as well as that derived from the molecular dynamic simulation in vacuo is quite different from those observed in the solid state and is very similar to that previously observed for the parent compound cyclo-(β-Ala-L -Pro-β-Ala-L -Pro). © 1993 John Wiley & Sons, Inc.     

The X-Pro peptide bond as an nmr probe for conformational studies of flexible linear peptides

The equilibrium between the cis and trans forms of X-Pro peptide bonds can readily be measured in the ¹³C nmr spectra. In the present paper we investigate how observation of this equilibrium could be used as an nmr probe for conformational studies of flexible polypeptide chains. The experiments include studies by ¹³C nmr of a series of linear oligopeptides containing different X-L -Pro peptide bonds, with X = Gly, L -Ala, L -Leu, L -Phe, D -Ala, D -Leu, and D -Phe. Overall the study confirms that X-Pro peptide bonds can generally be useful as ¹³C nmr probes reporting the formation of nonrandom conformation in flexible polypeptide chains. It was found that the cis–trans equilibrium of X-Pro is greatly affected by the side chain of X and the configuration of the α-carbon atom of X. On the basis of these observations some general rules are suggested for a practical applications of the X-Pro nmr probes in conformational studies of polypeptide chains.     

Reverse Relationship between α-Carbon Chirality and Helix Handedness in (αMe)Phe Peptides

Abstract

The crystal-state preferred conformations of two tripeptides, one tetrapeptide, and one pen- tapeptide, each containing a single residue of the chiral, C^α,α-disubstituted glycine C^α-methyl, C^α-benzylglycine [(αMe)Phe], have been determined by X-ray diffraction. The tripeptides are Z-L-(αMe)Phe-(Aib)₂-OH dihydrate and Z-Aib-D-(αMe)Phe-Aib-OtBu, the tetrapeptide is Z-(Aib)₂-D-(αMe)Phe-Aib-OtBu, and the pentapeptide is pBrBz-(Aib)₂-DL-(αMe)Phe-(Aib)₂-OtBu. While the two tripeptides are folded in a β-bend conformation, two such conformations are consecutively formed by the tetrapeptide. The pentapeptide adopts a regular 3₁₀-helix promoted by three consecutive β-bends. This study confirms the strong propensity of short peptides containing C^α-methylated α-aminoacids to fold into β-bends and 3₁₀-helical structures. Since Aib is achiral, the handedness of the observed bends and helices is dictated by the presence of the (αMe)Phe residue. In general, we have found that the relationship between (αMe)Phe chirality and helix handedness is opposite to that exhibited by protein aminoacids. A comparison with the preferred conformation of other extensively investigated C^α-methylated aminoacids is made.     

Stereochemical criteria for polypeptides and proteins. V. Conformation of a system of three linked peptide units

The general conformations of a system of three linked peptide units are studied, and it is found that there are three types of conformations which contain NH…O hydrogen bonding between the first and the third units. One of them is part of a 3₁₀-helix, while the other two arc nonhelical. The two nonhelical conformations are very similar, and in both the cases the peptide chain turns around, reversing the direction of progress. Such a conformation can therefore occur in the region where a polypeptide chain folds back on itself, as in the cross-β structure. The method of representing these interesting tripeptide conformations in a (?,ψ) map is described. Examples of such hydrogen-bonded, nonhelical conformations which occur in peptides and proteins are discussed—e.g., in cyclohexaglyeyl, an open tetrapeptide Gly-L -Pro-L -Leu-Gly, and in parts of the lysozyme chain.