Conformational studies on model dipeptides of Gly,L -Ala and their Cα-substituted analogs

As a part of the development of conformational guidelines for the design of metabolically altered peptidomimetics, we present conformational energy calculations on model dipeptide compounds with glycine (Gly), L-alanine (Ala), α-aminoisobutyric acid (Aib), L-tert-butylglycine (Tle), L-phenylglycine (Phg), (α,α)-diphenylglycine (Dφg), L-2-aminobutyric acid (Abu), 2-amino-2-ethylbutync acid (Deg), L-2-amino-2-vinylacetic acid (Ava) and (α,α)-divinylglycine (Dvg). The energy calculations have been made using molecular mechanics methods with a force field derived from MM2. The salient features are expressed in terms of conformational energy plots, drawn as a function of the backbone torsion angles φ(C_i-1′-N_i-C_i^α-C_i′) and ψ(N_i- C_i^α-N_{i + 1}). The low-energy structures of these compounds are qualitatively consistent with the X-ray crystal structure analyses of peptides and peptidomimetics. They are also in agreement with the results of the solution-phase studies carried out by NMR and IR techniques. The results obtained have important implications in the design of conformationally restricted peptidomimetics.     

Peptides from chiral Cα,α-disubstituted glycines Synthesis and characterization,conformational energy computations and solution conformational analysis of Cα-methyl,Cα-isopropylglycine [(αMe)Val] derivatives and model peptides*

Conformational energy computations on Ac-l -(αMe)Val-NHMe indicate that turns and right-handed helical structures are particularly stable conformations for this chiral Cα-methyl, Cα-alkylglycyl residue. We have synthesized and characterized a variety of l -(αMe)Val derivatives and peptides (to the pentamer level). The results of the solution conformational analysis, performed using infrared absorption, ¹H nuclear magnetic resonance, and circular dichroism, are in general agreement with those obtained from the theoretical investigation, in the sense that the l -(αMe)Val residue turns out to be a strong β-turn and right-handed helix former. A comparison is also made with the conclusions extracted from published work on peptides rich in other Cα-methyl, Cα-alkylglycyl residues.     

Peptides from chiral Cα,α-disubstituted glycines

The molecular and crystal structures of one derivative and three model peptides (to the pentapeptide level) of the chiral C^α,α-disubstituted glycine Cα-methyl, Cα-isopropylglycine [(αMe)Val] have been determined by X-ray diffraction. The derivative is mClAc-l -(α Me)Val-OH, and the peptides are Z-l -(αMe)Val-(l -Ala)₂-OMe monohydrate, Z-Aib-L-(αMe)Val-(Aib)₂-OtBu, and Ac-(Aib)₂-l -(αMe)Val-(Aib)₂OtBu acetonitrile solvate. The tripeptide adopts a type-I β-turn conformation stabilized by a 1 ← 4N-H . O=C intramolecular H-bond. The tetra- and pentapeptides are folded in regular right-handed 3₁₀-helices. All four L-(αMe)Val residues prefer φ, Ψ angles in the right-handed helical region of the conformational map. The results indicate that: (i) the (αMe)Val residue is a strong type-I/III β-turn and helix former, and (ii) the relationship between (αMe)Val chirality and helix screw sense is the same as that of Cα-monosubstituted protein amino-acids. The implications for the use of the (αMe)Val residue in designing conformationally constrained analogues of bioactive peptides are briefly discussed.     

Conformational investigation of α,β-dehydropeptides. IX. N-Acetyl-(E)-α,β-dehydrobutyrine N′-methylamide: stereoelectronic properties from infrared and theoretical studies*

Abstract: : The Fourier transform infrared spectra of Ac-(E)-ΔAbu-NHMe were analyzed to determine the predominant solution conformation (s) of this (E)-α,β-dehydropeptide-related compound and the electron density perturbation in its amide groups. The measurements were performed in dichloromethane and acetonitrile in the region of mode v_s (N–H), amide I, amide II and v_s (C^α= C^β). The equilibrium geometrical parameters, calculated by a method based on the density functional theory with the B3LYP functional and the 6–31G* basis set, were used to support spectroscopic interpretation and gain some deeper insight into the molecule. The experimental and theoretical data were compared with those of three previously described molecules: isomeric Ac-(Z)-ΔAbu-NHMe, Ac-ΔAla-NHMe, which is deprived of any β-substituent, and saturated species Ac-Abu-NHMe. The titled compound assumes two conformational states in equilibrium in the DCM solution. One conformer is extended almost fully and like Ac-ΔAla-NHMe is C₅ hydrogen-bonded. The other adopts a warped C₅ structure similar to that of Ac-(Z)-ΔAbu-NHMe. The C₅ hydrogen bond, unlike the H-bond in Ac-ΔAla-NHMe, is disrupted by acetonitrile. The resonance within the N-terminal amide groups in either of the (E)-ΔAbu conformers is not as well developed as the resonance in Ac-Abu-NHMe. However, these N-terminal groups, compared with the other unsaturated compounds, constitute better resonance systems in each conformationally related couple: the C₅ hydrogen-bonded Ac-(E)-ΔAbu-NHMe/Ac-ΔAla-NHMe and the warped C₅ Ac-(E)-ΔAbu-NHMe/Ac-(Z)-ΔAbu-NHMe. The resonance within the C-terminal groups of the latter couple apparently is similar, but less developed than the resonance in Ac-Abu-NHMe. The electron distribution within the C-terminal group of the hydrogen-bonded C₅ (E)-ΔAbu conformer apparently is determined mainly by the electron influx from the C^α= C^β double bond.     

New tools for the control of peptide conformation: the helicogenic Cα‐methyl,Cα‐cyclohexylglycine*

Abstract: The novel C^α‐tetrasubstituted α‐amino acid C^α‐methyl, C^α‐cyclohexylglycine was prepared by hydrogenation of its C^α‐methyl, C^α‐phenylglycine precursor. Terminally protected homodi‐, homotri‐, and homotetrapeptides from C^α‐methyl, C^α‐cyclohexylglycine and co‐oligopeptides to the pentamer level in combination with Gly or α‐aminoisobutyric acid residues were prepared by solution methods and fully characterized. The results of a conformational analysis, performed by use of Fourier transform infrared (FT‐IR) spectrophotomet absorption, ¹H NMR, and X‐ray diffraction techniques, support the contention that this C^α‐methylated, C^β‐trisubstituted aliphatic α‐amino acid is an effective β‐turn and 3₁₀‐helix inducer in tri‐ and longer peptides as its C^α‐methyl valine parent compound, but partially divergent from the corresponding aromatic C^α‐methyl, C^α‐diphenylmethylglycine residue, known to promote folded and fully extended structures to a significant extent in these oligomers.     

Structural versatility of peptides from Cα,α-disubstituted glycines: crystal-state conformational analysis of peptides from Cα-methylhomophenylalanine, (αMe)Hph

The molecular and crystal structures of the C^α-tetrasubstituted, δ-branched α-amino acid C^α-methyl-homophenylalanine, H-d -(αMe)Hph-OH, and three peptides (to the pentamer level), including the homotripeptide, have been determined by X-ray diffraction. The peptides are Z-l -(αMe)Hph-(l -Ala)₂-OMe, pBrBz-[d -(αMe)Hph]₃-OtBu and Ac-(Aib)₂-l -(αMe)Hph-(Aib)₂-OtBu. All the (αMe)Hph residues prefer φ,ψ torsion angles in the helical region of the conformational map. The two terminally blocked tripeptides adopt a β-bend conformation stabilized by a 1→4 C = O?H-N intramolecular H-bond. The terminally blocked pentapeptide is folded in a regular 3₁₀-helix. In general, the relationship between (αMe)Hph α-carbon chirality and helix handedness is the same as that exhibited by protein amino acids. A comparison is also made with the conclusions extracted from published work on peptides from other types of C^α-alkylated aromatic α-amino acids. © Munksgaard 1996.     

Protected 1–3 segment of the peptaibol antibiotics alamethicin and hypelcin.

A study of the modes of folding and self-association of Z-Aib-l -Pro-Aib-OMe (the protected 1–3 segment of the peptaibol antibiotics alamethicin and hypelcin) in the solid state was performed using i.r. absorption and X-ray diffraction. The stereochemically constrained tripeptide molecules adopt a 4 ± 1 intramolecularly H-bonded form (β-turn), where the single intramolecular H-bond is found between the peptide N-H group of the Aib³ residue and the urethane C = O group of the N-blocking benzyloxycarbonyl moiety. This folded structure is stabilized by an intermolecular H-bond between the urethane N-H group of the Aib¹ residue and the peptide C = O group of the Pro² residue of a symmetry related molecule. According to the i.r. absorption data, in CH₂Cl₂ and TMP solutions the same intramolecularly H-bonded form occurs as that found in solid state. Compared to the situation in the solid state, in CH₂Cl₂ and TMP solvation of the urethane N-H group replaces self-association (through the same N-H group). The results are also discussed in relation to those obtained for other protected -Aib-X-Aib-(X = Aib, l -Ala, l -Val) tripeptide segments of peptaibol antibiotics.     

A topographically and conformationally constrained,spin‐labeled, α‐amino acid: crystallographic characterization in peptides*

Abstract: 2,2,6,6‐Tetramethylpiperidine‐1‐oxyl‐4‐amino‐4‐carboxylic acid (TOAC) is a topographically and conformationally restricted, nitroxide containing, C^α‐tetrasubstituted α‐amino acid. Here, we describe the molecular and crystal structures, as determined by X‐ray diffraction analyses, of a TOAC terminally protected derivative, the cyclic dipeptide c(TOAC)₂·1,1,1,3,3,3‐hexafluoropropan‐2‐ol (HFIP) solvate, and five TOAC‐containing, terminally protected, linear peptides ranging in length from tetra‐ to hepta‐peptides. Incipient and fully developed, regular or distorted 3₁₀‐helical structures are formed by the linear peptides. A detailed discussion on the average geometry and preferred conformation for the TOAC piperidine ring is also reported. The X‐ray diffraction structure of an intramolecularly cyclized side product resulting from a C‐activated TOAC residue has also been determined.     

Conformational properties of hybrid peptides containing α‐ and ω‐amino acids*

Abstract: This review briefly surveys the conformational properties of guest ω‐amino acid residues when incorporated into host α‐peptide sequences. The results presented focus primarily on the use of β‐ and γ‐residues in αω sequences. The insertion of additional methylene groups into peptide backbones enhances the range of accessible conformations, introducing additional torsional variables. A nomenclature system, which permits ready comparisons between α‐peptides and hybrid sequences, is defined. Crystal structure determination of hybrid peptides, which adopt helical and β‐hairpin conformations permits the characterization of backbone conformational parameters for β‐ and γ‐residues inserted into regular α‐polypeptide structures. Substituted β‐ and γ‐residues are more limited in the range of accessible conformation than their unsubstituted counterparts. The achiral β,β‐disubstituted γ‐amino acid, gabapentin, is an example of a stereochemically constrained residue in which the torsion angles about the C^β–C^γ (θ₁) and C^α–C^β (θ₂) bonds are restricted to the gauche conformation. Hybrid sequences permit the design of novel hydrogen bonded rings in peptide structures.     

Conformational investigation of α, β-dehydropeptides. VIII.*N-Acetyl-α, β-dehydroamino acid N'-methylamides: conformation and electron density perturbation from infrared and theoretical studies

The Fourier transform infrared spectra are analyzed in the regions of v_s(N-H), amide I, amide II and v_s(C^α=C^β) bands for a series of Ac-ΔXaa-NHMe, where ΔXaa =ΔAla, (Z)-ΔAbu, (Z)-ΔLeu, (Z)-ΔPhe and AVal, to determine the predominant solution conformation of these α, β-dehydropeptide-related molecules and the electron distribution perturbation in their amide bonds. The measurements were performed in dichloromethane (DCM). To confirm and rationalize the assignments, the spectra of the respective series of saturated Ac-Xaa-NHMe, recorded in DCM, and the spectra of these two series of unsaturated and saturated compounds, recorded in acetonitrile, were examined. To help interpret the spectroscopic results, the equilibrium geometrical parameters for some selected amides were used. These were optimized with ab initio methods in the 6-31G** basis set. Each of the dehydroamides studied adopted a C₅ structure, which in Ac-ΔAla-NHMe is fully extended and accompanied by the strong C₅ hydrogen bond. Interaction with the C^α=C^β bond lessened the amidic resonance within each of the flanking amide groups. The N-terminal C=O bond was noticeably shorter, both amide bonds were longer than the corresponding bonds in the saturated entities and the N-terminal amide system was distorted. Ac-ΔAla-NHMe constituted an exception. Its C-terminal amide bond was shorter than the standard one and both amide systems were prototypically planar.     

Non coded Cα,α-disubstituted amino acids

The crystal and molecular structure of the fully protected dipeptide Boc-Val-(S)-α-MeSer-OMe has been determined by X-ray diffraction techniques. Crystals grown from ethyl acetate/n-pentane mixtures are tetragonal, space group 14₁, with cell parameters at 295 K of a= 15.307(2), c= 18.937(10)Å, V = 4437.1 ų, M.W. = 332.40, Z = 8, D_m= 0.99 g/cm³ and D_x= 0.995 g/cm³. The structure was solved by application of direct methods and refined to an R value of 0.028 for 1773 reflections with I≥3σ(I) collected on a CAD-4 diffractometer. Both chiral centers have the (S) configuration. The dipeptide assumes in the solid state an S shape. The urethane moiety is in the cis conformation, while the amide bond is in the common trans conformation. The conformational angles φ₁, ψ₁ of the Val and φ₂, and ψ₂ of the (S)-αMeSer fall in the F region of the φ-ψ map. The isopropyl side chain of the Val residue has the (t, g^?) conformation, while the Ser side chain has a g⁺ conformation. The hydrogen bond donor groups are all involved in intermolecular H-bond interactions. Along the quaternary axis the dipeptide molecules are linked to each other with the formation of infinite rows.     

Conformational investigation of α, β-dehydropeptides

The crystal structure of Ac-Pro-ΔVal-NHCH₃ was examined to determine the influence of the α,β-dehydrovaline residue on the nature of peptide conformation. The peptide crystallizes from methanol-diethyl ether solution at 4° in needle-shaped form in orthorhombic space group P2₁2₁2₁ with a= 11.384(2) Å, b = 13.277(2) Å, c = 9.942(1) Å. V = 1502.7(4) ų Z = 4, D_m= 1.17 g cm^?3 and D_c=1.18 g cm^?3 The structure was solved by direct methods using SHELXS-86 and refined to an R value of 0.057 for 1922 observed reflections. The peptide is found to adopt a β-bend between the type I and the type III conformation with φ₁=?68.3(4)°, ψ₁=? 20.1(4)°, φ₂=?73.5(4)°= and Ψ₂=?14.1(4)°=. An intramolecular hydrogen bond between the carbonyl oxygen of ith residue and the NH of (i+ 3)th residue stabilizes the β-bend. An additional intermolecular N.,.O hydrogen bond joins molecules into infinite chains. In the literature described crystal structures of peptides having a single α,β-dehydroamino acid residue in the (i+ 2) position and forming a β-bend reveal a type II conformation.     

(αMe)Aun: a highly lipophilic,chiral, Cα‐tetrasubstituted α‐amino acid. Incorporation into model peptides and preferred conformation

Abstract: Using a chemo‐enzymatic approach we prepared the highly lipophilic, chiral, C^α‐methylated α‐amino acid (αMe)Aun. Two series of terminally protected model peptides containing either d ‐(αMe)Aun in combination with Aib or l ‐(αMe)Aun in combination with Gly were synthesized using solution methods and fully characterized. A detailed solution conformational analysis, based on FT‐IR absorption, ¹H NMR and CD techniques, allowed us to determine the preferred conformation of this amino acid and the relationship between chirality at its α‐carbon atom and screw sense of the helix that is formed. The results obtained strongly support the view that d ‐(αMe)Aun favors the formation of the left‐handed 3₁₀‐helical conformation.     

Conformational versatility of the Nα-acylated tripeptide amide tail of oxytocin

The synthesis, physical and analytical characterization, and crystal-state structural analysis by X-ray diffraction of three analogues of the N^α-acylated tripeptide amide tail of oxytocin, each containing a cyclic C^{α, α-} disubstituted glycine at position 2, have been performed. The peptides arc Boc-L-Pro-Ac₃c-Gly-NH₂, Z-L-Pro-Ac₅c-Gly-NH₂ and Z-L-Pro-Ac₅c-Gly-NH₂. While the former is folded in a type-II β-turn conformation at the -L-Pro-Ac₃c- sequence, the two latter tripeptides form two consecutive (type-II, type-I′) β-turns. The Ac₅c- and Ac₆c-tripeptides are the first examples of such a highly folded structural combination in a position-2 analogue of the N^α-acylated -L-Pro-L-Leu-GIy-NH² sequence.     

Crystallographic characterization of conformation of 1-aminocyclopropane-1-carboxylic acid residue (Ac3c) in simple derivatives and peptides*

The molecular and crystal structures of the C^α,α-dialkylated α-amino acid residue 1-aminocyclopropane-1-carboxylic acid hemihydrate (H₂^⊕-Ac₃c-O^?·½ H₂O) and nine derivatives and dipeptides have been determined by X-ray diffraction. The derivatives are pBrBz-Ac₃c-OH, Piv-Ac₃c-OH, Z-Ac₃c-OH, the α- and β-forms of t-Boc-Ac₃c-OH, Z-Ac₃c-OMe, and the 5(4H)-oxazolone from pBrBz-Ac₃c-OH; the dipeptides are H-(Ac₃c)₂-OMe and c(Ac₃c)₂. The values determined for the torsion angles about the N-C^α (φ) and C^α-C′ (φ) bonds for the single Ac₃c residue of Piv-Ac₃c-OH, the α- and β-forms of t-Boc-Ac₃-OH and Z-Ac₃c-OMe, and the C-terminal Ac₃c residue of H-(Ac₃c)₂-OMe correspond to folded conformations in the “bridge” region of the Ramachandran map. The structures of pBrBz-Ac₃c-OH and Z-Ac₃c-OH, however, are unusual in having a semi-extended conformation for the φ,ψ angles. The N-terminal Ac₃c residue of H-(Ac₃c)₂-OMe adopts a novel type of C₅ conformation, characterized inter alia by an (amino) N ? H-N (peptide) intramolecular hydrogen bond. While the acyl N^α-blocking groups form trans amides (pBrBz-Ac₃c-OH and Piv-Ac₃c-OH), the urethane groups may adopt either the trans [Z-Ac₃c-OH and t-Boc-Ac₃c-OH(α-form)] or the cis amide conformations [t-Boc-Ac₃c-OH(β-form) and Z-Ac₃c-OMe]. The five- and six-membered rings of the 5(4H)-oxazolone and the 2,5-dioxopiperazine, respectively, are planar. The four independent molecules in the asymmetric unit of the free α-amino acid are zwitterionic.     

Ac10c: a medium‐ring,cycloaliphatic Cα,α‐disubstituted glycine. Incorporation into model peptides and preferred conformation

Abstract: Two complete series of N‐protected oligopeptide esters to the pentamer level from 1‐amino‐cyclodecane‐1‐carboxylic acid (Ac₁₀c), an α‐amino acid conformationally constrained through a medium‐ring C^α_i ? C^α_i cyclization, and either the l ‐Ala or Aib residue, along with the N‐protected Ac₁₀c monomer and homo‐dimer alkylamides, were synthesized using solution methods and fully characterized. The preferred conformation of these model peptides was assessed in deuterochloroform solution using FT‐IR absorption and ¹H NMR techniques. Furthermore, the molecular structures of two derivatives (Z‐Ac₁₀c‐OH and Fmoc‐Ac₁₀c‐OH) and two peptides (the dipeptide ester Z‐Ac₁₀c‐l ‐Phe‐OMe and the tripeptide ester Z‐Aib‐Ac₁₀c‐Aib‐OtBu) were determined in the crystal state using X‐ray diffraction. The experimental results support the view that β‐bends and 3₁₀‐helices are preferentially adopted by peptides rich in Ac₁₀c, the third largest cycloaliphatic C^α,α‐disubstituted glycine known. This investigation allowed us to complete a detailed conformational analysis of the whole 1‐amino‐cycloalkane‐1‐carboxylic acid (Ac_nc, with n = 3–12) series, which represents the prerequisite for our recent proposal of the ‘Ac_nc scan’ concept.     

(αMe)Nva: stereoselective syntheses and preferred conformations of selected model peptides

Abstract: Using different stereoselective chemical and chemoenzymatic approaches we synthesized the chiral, C^α‐methylated α‐amino acid l ‐(αMe)Nva with a short, linear side‐chain. A set of terminally protected model peptides to the pentamer level containing either (αMe)Nva or Nva in combination with Ala and/or Aib was prepared using solution methods and characterized fully. Two (αMe)Nva peptides were also synthesized using side‐chain hydrogenation of the corresponding C^α‐methyl, C^α‐allylglycine (Mag) peptides. A detailed solution and crystal‐state conformational analysis based on FT‐IR absorption, ¹H NMR and X‐ray diffraction techniques allowed us to define that: (i) (αMe)Nva is an effective β‐turn and 3₁₀‐helix former; and (ii) the relationship between (αMe)Nva chirality and the screw sense of the turn/helix formed is that typical of protein amino acids, i.e. l ‐(αMe)Nva induces the preferential formation of right‐handed folded structures. In more general terms, this study reinforced previous conclusions that peptides based on α‐amino acids with a C^α‐methyl substituent and a C^α‐linear alkyl substituent are characterized by a strong tendency to fold into turn and helical structures.     

Conformational investigation of α,β-dehydropeptides VII*. Conformation of Ac-Pro-ΔAla-NHCH3 and Ac-Pro-(E)-ΔAbu-NHCH3: comparison with (Z)-substituted α,β-dehydropeptides†

The crystal structure and solution conformation of Ac-Pro-ΔAla-NHCH₃ and the solution conformation of Ac-Pro-(E)-ΔAbu-NHCH₃ were investigated by X-ray diffraction method and NMR, FTIR and CD spectroscopies. Ac-Pro-ΔAla-NHCH, adopts an extended-coil conformation in the crystalline state, with all-trans peptide bonds and the ΔAla residue being in a C₅ form, φ₁=– 71.4(4), ψ₁=– 16.8(4), φ₂=– 178.4(3) and ψ₂= 172.4(3)°. In inert solvents the peptide also assumes the C₅ conformation, but a γ-turn on the Pro residue cannot be ruled out. In these solvents Ac-Pro-(E)- ΔAbu-NHCH₃ accommodates a βII-turn, but a minor conformer with a nearly planar disposition of the CO—NH and C=C bonds (φ₂～0°) is also present. Previous spectroscopic studies of the (Z)-substituted dehydropeptides Ac-Pro-(Z)- ΔAbu-NHCH, and Ac-Pro-ΔVal-NHCH₃ reveal that both peptides prefer a βII-turn in solution. Comparison of conformations in the family of four Ac-Pro-ΔXaa-NHCH₃ peptides let us formulate the following order of their tendency to adopt a β-turn in solution: (Z)- ΔAbu > (E)- δAbu > ΔVal; ΔAla does not. None of the folded structures formed by the four compounds is stable in strongly solvating media. © Munksgaard 1996.     

Stereochemical analysis of the antigenic tip of the V3 loop peptide of HIV-1 gp120

A novel multiple turn conformation has been observed for a segment GPGRAFY in the crystal structure of a complex of HIV-1 gp120 V3 loop peptide with the Fab fragment of a neutralizing antibody [Ghiara et al. (1994) Science 264 , 82–85]. A structural motif has been defined for the peptide segment, employing idealized backbone conformations characterized by ranges of virtual C^α torsion angles and bond angles. A search of 122 high-resolution protein crystal structures has permitted identification of 24 examples of similar structural motifs. Two major conformational families have been identified, which differ primarily in the conformation at residue 3. The observed conformation at residue 3 in family 1 is left-handed helical (α_L) and that in family 2 is right-handed helical (α_R). Of the 10 examples in family 1, 9 examples have Gly residues at position 3. Of the 12 examples in family 2, 7 examples have Asn/Asp at position 3. Computer modeling of the V3 loop tip sequence using the two backbone conformational families as starting points leads to minimum-energy conformations in which antigenically important side-chains occupy similar spatial arrangements. This stereo-chemical analysis of the V3 loop tip sequence suggests a rational basis for the design of synthetic analog peptides for use as viral antagonists or synthetic antigens. © Munksgaard 1995.     

Insights into the determinants of β‐sheet stability: 1H and 13C NMR conformational investigation of three‐stranded antiparallel β‐sheet‐forming peptides

Abstract: In a previous study we designed a 20‐residue peptide able to adopt a significant population of a three‐stranded antiparallel β‐sheet in aqueous solution (de Alba et al. [1999]Protein Sci. 8, 854–865). In order to better understand the factors contributing to β‐sheet folding and stability we designed and prepared nine variants of the parent peptide by substituting residues at selected positions in its strands. The ability of these peptides to form the target motif was assessed on the basis of NMR parameters, in particular NOE data and ¹³C_α conformational shifts. The populations of the target β‐sheet motif were lower in the variants than in the parent peptide. Comparative analysis of the conformational behavior of the peptides showed that, as expected, strand residues with low intrinsic β‐sheet propensities greatly disfavor β‐sheet folding and that, as already found in other β‐sheet models, specific cross‐strand side chain–side chain interactions contribute to β‐sheet stability. More interestingly, the performed analysis indicated that the destabilization effect of the unfavorable strand residues depends on their location at inner or edge strands, being larger at the latter. Moreover, in all the cases examined, favorable cross‐strand side chain–side chain interactions were not strong enough to counterbalance the disfavoring effect of a poor β‐sheet‐forming residue, such as Gly.