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⁺.     

Crystal structure and conformation of a cyclic tetrapeptide cyclo(L-Pro-Sar)2 containing all-cis peptide units

The crystal structure and conformation of the synthetic cyclic tetrapeptide, cyclo(L -Pro-Sar)₂, was determined by x-ray analysis. The peptide crystallizes in the orthorhombic space group P2₁2₁2₁ with cell parameters a = 9.277(1), b = 12.884(1), and c = 15.581(2) Å. The crystal structure was solved by the symbolic addition procedure for direct phase determination and least-squares refinement using 1796 reflections, which led to the final R value of 0.043. This structure provides the first example observed in a crystal of a cyclic tetrapeptide in which all four peptide units have been found in the cis conformation with ω angles deviating slightly by 2°–10° from the ideal value of 0°. It was also found that the two Pro C^α-CO single bonds assumed a trans′ (ψ = 159.6° and 158.4°) conformation. Adjoining average planes of the peptide groups fall at nearly right angles to each other. The pyrrolidine ring conformations of the two prolyl residues are in the envelope form, with C^γ carbon out of the least-squares planes for the remaining four atoms.     

Nmr and computer-aided studies of the three interchanging stereoisomers of the cyclic hexapeptide cyclo[-Pro1-Gly2-Glu3(OBzl)-Pro4-Phe5-Leu6-]: Unexpected observation of a cis isomer of a secondary amide peptide bond in the presence of two trans proline peptide bonds

The cyclic hexapeptide cyclo[-Pro¹-Gly²-Glu³(OBzl)-Pro⁴-Phe⁵-Leu⁶-] ( 1 ; OBzl: benzyl ester) was modeled and synthesized to be used as a chiral site for the separation of enantiomers. Total correlation spectroscopy and nuclear Ovehauser effect spectroscopy spectra of the peptide in CDCl₃ showed the presence of three stereoisomers. The two dominant stereoisomers 1a and 1b exchanged chemically with each other, while the minor stereoisomer 1c exchanged exclusively with the stereoisomer 1b . Stereoisomer 1a had two cis proline peptide bonds while stereoisomer 1b had all-trans peptide bonds. The stereoisomer 1c had, for nonstrained peptides, an unusual cis phenylalanine peptide bond while both proline peptide bonds were trans. © 1993 John Wiley & Sons, Inc.     

Conformations of cyclic peptide/calcium complexes in solution

Synthetic cyclic octapeptides of general structure cyclo[Glu(γOBzl)-Sar-Gly-(N-R)Gly]₂ (R = n-hexyl and cyclohexyl) transport calcium ions selectively across organic phases and phospholipid membranes. We have now used proton nmr spectroscopy (360 MHz) to study the solution conformation(s) of their calcium complexes. When Ca(ClO₄)₂ was added to solutions of these peptides in CDCl₃, nmr spectra of the resulting calcium complexes were characteristic of a single C₂-symmetric conformer. From a Karplus-Bystrov analysis of vicinal coupling constants in both the peptide backbone and Glu side chain (treated as an ABCC′MX spin system), in conjuction with model-building studies, a structure was proposed in which the calcium ion is bound in an octahedral-type complex by the four (coplanar) carbonyl groups of the (all-trans) Glu-Sar and Gly-(N-R)Gly peptide bonds. Occurrence of preferred rotamers about Glu side chain C^α–C^β bonds indicated that restricted rotation in peptide side chains arises upon calcium binding.     

Synthesis and conformation of the cyclic octapeptides cyclo(Phe-Pro)4, cyclo(Leu-Pro)4, and cyclo[Lys(Z)-Pro]4

Cyclic octapeptides, cyclo(X-Pro)₄, where X represents Phe, Leu, or Lys(Z), were synthesized and their conformations investigated. A C₂-symmetric conformer containing two cis peptide bonds was found in all of these cyclic octapeptides. The numbers of available conformations due to the cis–trans isomerization of Pro peptide bonds depended on the nature of the solvent and X residue: they decreased in the following order: cyclo[Lys(Z)-Pro]₄ > cyclo(Leu-Pro)₄ > cyclo(Phe-Pro)₄ in CDCl₃. ¹³C spin-lattice relaxation times (T₁) of these cyclic octapeptides were measured, and the contribution of segmental mobility to T₁ was found to vary with the nature of the X residue.     

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.     

Multiple interconverting conformers of the cyclic tetrapeptide tentoxin, [cyclo-(L-MeAla1-L-Leu2-MePhe[(Z)Δ]3-Gly4)], as seen by two-dimensional 1H-nmr spectroscopy

The conformations of the phytotoxic cyclic tetrapeptide tentoxin [cyclo-(L -MeAla¹-L -Leu²-MePhe[(Z)Δ]³-Gly⁴ )] have been studied in aqueous solution by two-dimensional proton nmr at various temperatures. Contrary to what is observed in chloroform, tentoxin exhibits multiple exchanging conformations in water. Aggregation phenomena were also observed. Four conformations with different proportions (51, 37, 8, and 4%) were observed at ?5°C. Models were constructed from nmr parameters and restrained molecular dynamics simulations. All the models exhibit cis-trans-cis-trans conformation of the amide bond sequence. The conversion from one form to another is accomplished by a conformational peptide flip consisting of a 180° rotation of a nonmethylated peptide bond. © 1995 John Wiley & Sons, Inc.     

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.     

Studies on cyclic peptides. IV. Conformation of cyclo(Sar-Sar-Gly)2, cyclo(Sar)6 and cyclo(Sar-Gly-Gly)2 and their conformational change induced by alkali thiocyanates

Conformation of cyclo (Sar-Sar-Gly)₂, cyclo(Sar)₆, and cyclo(Sar-Gly-Gly)₂ was investigated by nmr spectroscopy. cyclo(Sar-Sar-Gly)₂, were shown to assume various conformations in dimethysulfoxide. It was attributed to the distribution of cis as well as trans Gly-Sar or Sar-Sar amide links along the peptide backbone. In particular, cyclo(Sar-Sar-Gly)₂ took five or six different conformations: one or three C₂-symmetric conformations and four or three asymmetric conformations, respectively. Three of nine NH resonance signals were ascribed to the internally hydrogen-bonded glycine residues. cyclo(Sar-Sar-Gly)₂ and cyclo(Sar)₆ showed a spectral change on the addition of alkali thiocyanates, indicating a conformational change induced by a complex formation with the alkali cations. The complex nmr spectrum due to a hybridization of different conformations changed with the salt addition into a simple nmr spectrum, suggesting a preponderence of a new, single conformation. On the basis of the spectral change, the strength for the cations binding the cyclic peptides was found to be in the order of K⁺ > Na⁺ > Rb⁺ > Cs⁺ for cyclo(Sar-Gly-Gly)₂ and K⁺ > Rb⁺ > Cs⁺ for cyclo(Sar)₆. On the other hand, cyclo(Sar-Gly-Gly)₂ in dimethylsulfoxide assumed a single C₂ conformation having two glycyl peptide protons shielded from solvent and the other two exposed to solvent. This conformation did not change with the salt addition. Finally, the conformations of several cyclic peptides containing the sarcosine residue such as cyclo(Sar)₆ cyclo(Sar-Sar-Gly)₂ cyclo(Pro-Sar-Gly)₂, and cyclo (Sar-Gly-Gly)₂ were compared. It appeared that proline and glycine residues reduced the conformational multiplicity of the cyclic peptide backbone, and the ability to bind alkali metal cations decreased in the above order.     

1H nuclear magnetic resonance studies of N-acetyl-L-proline N-methylamide. Molecular conformations,hydrogen bondings,and thermodynamic quantities in various solvents

Concentration and temperature dependences of the ¹H nmr spectra of N-acetyl-L -proline N-methylamide were observed in various solvents [CCl₄, CDCl₃, (CD₃)₂CO, (CD₃)₂SO, H₂O, and D₂O]. The fraction of the cis isomer (with respect to the bond between the acetyl carbonyl carbon and prolyl nitrogen atoms) depends greatly on the solvent used; the fraction of the cis isomer is higher in polar solvents than in nonpolar solvents. It depends also on concentration and temperature in nonpolar solvents but not in polar solvents. In nonpolar solvents the trans isomer mostly exists in the γ-turn structure with an intramolecular hydrogen bond and the cis isomer tends to form molecular aggregates by intermolecular hydrogen bonds. In polar solvents both the cis and trans isomers exist in monomeric forms which interact with solvent molecules. The pH dependences of the N-methyl proton resonances indicate that the γ-turn structure of the trans isomer is present also in aqueous solution, though its population is difficult to determine. Apparent enthalpy and entropy changes for the conversion of the trans isomer to cis isomer are evaluated for various solvents. The results are discussed in terms of the intra- and intermolecular hydrogen bondings.     

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.     

Flexibility of the pyrrolidine ring in proline peptides

A survey of over 50 crystal structures indicates that both imino acid and peptide derivatives of proline populate ring conformers consistent with the torsional potentials about single bonds. In both cases, lower barriers for rotation about C? N bonds relative to those about C? C bonds favor smaller values for dihedral angles about the former bonds. In peptides a minimum in the torsional potential about C? N bonds occurs at zero dihedral angle, further favoring small angles. The pyrrolidine-ring dihedral angles of the proline compounds in the solid state obey a cyclopentane-type pseudorotation function. Thus the puckering of the five-membered ring can be quantitatively described by two parameters. Consistent with small dihedral angles about C? N bonds, C^β and/or C^γ are puckered out of the mean plane of the ring in nearly all of the nonstrained compounds. Utilizing the consistent force-field method of Lifson and coworkers [see A. Warshel, M. Levitt, and S. Lifson (1970) J. Mol. Spectrosc. 33 , 84] the intramolecular energy of five proline peptides was minimized with respect to all internal coordinates. In addition, the energy surface near minima was explored by constraining a particular dihedral angle and reminimizing the energy with respect to all remaining variables. In linear peptides two types of pyrrolidine-ring conformers have identical predicted energies. In the cyclic dipeptide cyclo (Pro-Gly) one of the ring conformers is favored by about 3 kcal/mol, while the cyclic tripeptide cyclo(Pro-Gly-Gly) favors the other conformer by a comparable margin. In agreement with observations in the solid state and in solution, C^β and/or C^γ are puckered in the predicted conformers. A correlation between proline Φ and the details of the puckered conformation was predicted and found to match precisely conformers observed in crystals. For the diamides N-acetyl-L -proline-N′-methyl-amide and N-acetyl-L -proline-N′,N′-dimethylamide (AcProMe₂A) 30% and 60% cis acetyl peptide bonds were predicted in good agreement with observations in nonpolar solvents for the respective compounds. The conformational distributions with respect to proline Ψ are also in accord with experimental observations. For AcProMe₂A, a model for a -Pro-Pro-sequence in a peptide chain, this study is the first to predict stable conformers for proline Ψ either ca. ?50° or 140° for both cis and trans peptides.     

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.     

Standard dimensions forcis N-methyl peptide unit and flexibility ofcis peptide units

The mean dimensions of thecis N-methyl peptide unit have been arrived at by analysing the crystal structure data on compounds containing such units. These dimensions can be used as standard in conformational studies on cyclic peptides. While the bonds meeting at C are almost coplanar, those meeting at N show a slight pyramidal disposition. A comparison of the dimensions of the normal and N-methylatedcis peptide units show that there are perceptible differences in the parameters connected with N. In addition, the flexibility of thecis peptide unit has been analysed by studying the distribution of the parameters in different classes of compounds such as cyclic di, tri and higher peptides. The salient features are: (i) The angle C^αCN in cyclic dipeptide and the angle C^δNC^α in higher peptides tend to be lower, when the peptide unit is associated with a prolyl residue; (ii) in cyclic tripeptides the internal anglesviz., C^αCN and CNC^α are significantly larger thereby increasing the intra-annular space; (iii) the bond C^α-C is distinctly shorter when it occurs in cyclic dipeptides. The results lead to the conclusion that thecis peptide unit takes up aneed-based flexibility in its dimension.     

Cis–trans peptide-bond equilibria in cyclic hexapeptides

Data are presented on the position of the equilibria of cyclo(Xxx-Pro-Yyy)₂ backbones between forms with two cis Xxx-Pro peptide bonds and forms with only trans peptide bonds. These data are interpreted in terms of two factors: a solvent-independent steric interaction between the Xxx and Pro side chains, and the ability of solvent to influence the transannular electrostatic interaction between N? H and C?O groups of the Xxx units in the all-trans form.     

Conformational characteristics of polypeptides containing isolated L-proline residues with cis peptide bonds

The conformational characteristics of the peptide sequence X-l-Pro, where X  Gly or l-Ala and the peptide bond joining X and l-Pro is cis, are evaluated. Semi-empirical potential functions are used to estimate the contributions to the conformational energy made by the non-bonded van der Waals' and electrostatic interactions and the intrinsic torsional potentials about the NC^a and C^aC′ bonds. Rotations φ₁ and ψ₁ about the NC^a and C^aC′ bonds in residue X and rotation ψ₂ about the C^aC′ bond in l-Pro are permitted, while the angle of rotation φ₂ about the NC^a bond in l-Pro is fixed at 120 ° by the pyrrolidine ring. The presence of the cis peptide bond connecting X and l-Pro renders the backbone rotations φ₁, ψ₁ in X dependent upon the rotation ψ₂ about the C^aC′ bond in l-Pro. (Interdependence of rotations in neighboring residues joined by a cis peptide bond was previously observed in l-alanine oligomers.) The number of energetically allowed conformations for the Gly and l-Ala residues preceding a cis peptide bond l-Pro residue are found to be substantially reduced from those permitted when the peptide bond is trans or when l-Pro is replaced by an amino acid residue. On the other hand, ψ₂ = 100 to 160 ° (cis′) and 300 to 0 ° (trans′) are found to be the lowest energy conformations of the l-Pro residue irrespective of the cis or trans conformation of the X-l-Pro peptide bond.     

Formation of several stable complexes between the minor components of the cyclic tetrapeptide cyclo-(-Pro1-Ala2-D-Phe3-Leu4-) and some specific Boc-amino acids

The cyclic tetrapeptide cyclo(-Pro¹-Ala²-D -Phe³-Leu⁴-) was modeled and synthesized to be used for molecular interactions and chiral discrimination studies in CDCl₃. Total correlation spectroscopy and nuclear Overhauser effect spectroscopy spectra of the cyclic tetrapeptide showed the presence of one dominant stereoisomer— 1 —and three minor ones— 2a , 2b , and 2c —in a relationship of 92:6:1:1. They formed three- to five-hydrogen bond complexes with Boc-D -Ser, Boc-L -Ser and Boc-L -Thr (Boc: t-butyloxylcarbonyl). These three Boc-amino acids interact more strongly with 2a , 2b , and 2c than with 1 , altering their relative concentrations to 48:40:6:6. In the complex between the cyclic tetrapeptide and Boc-D -Ser, the stereoisomer 2a exchanged chemically with 1 , 2b , and 2c , while 1 did not exchange with either 2b or 2c . This chemical exchange is due to cis-trans isomerization of the peptide bonds. The chiral discrimination of 2a , 2b , and 2c was stronger than that of 1 . No complexation occurred with Boc-L -Ala or Boc-L -Trp. © 1993 John Wiley & Sons, Inc.     

15N-nmr spectroscopy. 20. Cis/trans isomerism and neighboring residue effects of proline-containing peptides

Five N-protected tetrapeptide esters of the structure Gly-Pro-X-X*-O-methyl were synthesized in such a way that one of the two variable amino acid residues (X) was isotopically enriched in ¹⁵N (denoted by*). The variable amino acids are glycine, alanine, leucine, valine, and phenylalanine. For the natural abundance ¹⁵N-nmr spectra of these tetrapeptide derivatives in methylene chloride only the signals of the Gly-Pro trans isomer were found. In a 2:1 mixture of acetone and dimethylsulfoxide, signals for both the cis and trans isomers were observed. Three of the five tetrapeptide derivatives show cis/trans splitting of all four nitrogen signals. The ¹⁵N-nmr spectra of Z-Pro-Pro-OH and of (D ,L -proline)_n were measured in a 2:1 mixture of acetone and dimethylsulfoxide as well as in water. The effects of solvents and neighboring residues and the influence of the cis/trans isomerism on the nmr spectra are discussed. The determination of the cis/trans equilibria and the assignment of the ¹⁵N-nmr signals of all oligopeptides were achieved by selective isotopic enrichment and by means of ¹³C-nmr spectra.     

Biotransformation of Unsaturated Long-Chain Fatty Acids by Eubacterium lentum

Eubacterium lentum (33 strains) isomerized the 12-cis double bond of C₁₈ fatty acids with cis double bonds at C-9 and C-12 into an 11-trans double bond before reduction of the 9-cis double bond. The 14-cis double bond of homo-γ-linolenic acid was isomerized by 29 strains into a 13-trans double bond. The same strains isomerized the 14-cis double bond of arachidonic acid into a 13-trans double bond and then isomerized the 8-cis double bond into a 7-trans double bond; the 13-cis double bond of 10-cis, 13-cis-nonadecadienoic acid was isomerized into a 12-trans double bond. None of these isomerization products was further reduced. Studies with resting cells showed optimal isomerization velocity at a linoleic acid concentration of 37.5 μM; higher concentrations were inhibitory. The pH optimum for isomerization was 7.5 to 8.5. The isomerase was inhibited by the sulfhydryl reagents iodoacetamide, bromoacetate, and N-ethylmaleimide and by the chelators EDTA and 1,10-phenanthroline.     

Synthesis and conformation of cyclic hexapeptide cyclo(Pro-Sar-Sar)2

A cyclic hexapeptide, cyclo(Pro-Sar-Sar)₂, which consists of N-substituted amino acids only was synthesized, and its solution conformation was investigated by n.m.r. spectroscopy. Seven different C₂-symmetric conformations were detected, which were distinguishable from each other on the n.m.r. time scale. This is due to the cis/trans isomerization of N-substituted peptide bonds. Allowed C₂-symmetric conformations were computed on the basis of a hard-sphere model. Some conformations detected in n.m.r. spectra were not allowed in the calculation. This disagreement suggests that some asymmetric conformations with regard to the single bond rotation are averaged out due to a rapid rotation on the n.m.r. time scale. These points indicate that the molecule of cyclo (Pro-Sar-Sar)₂ is very flexible