Synthesis, and crystal and molecular structure of the 3(10)-helical alpha,beta-dehydro pentapeptide Boc-Leu-Phe-Ala-delta Phe-Leu-OMe

Two phosphonodehydrotripeptides: Boc0–Gly1–Δ(Z)Phe2–α-Abu3PO3Me2and Boc0–Gly1–Δ(Z)Phe2–α-Nva3PO3Et2

The present paper reports the crystal structures of two short phosphonotripeptides (one in two crystal forms) containing one ΔPhe (dehydrophenylalanine) residue, namely dimethyl (3-{[tert-butoxycarbonylglycyl-α,β-(Z)-dehydrophenylalanyl]amino}propyl)phosphonate, Boc0–Gly1–Δ(Z)Phe2–α-Abu3PO3Me2, C21H32N3O7P, (I), and diethyl (4-{[tert-butoxycarbonylglycyl-α,β-(Z)-dehydrophenylalanyl]amino}butyl)phosphonate, Boc0–Gly1–Δ(Z)Phe2–α-Nva3PO3Et2, as the propan-2-ol monosolvate 0.122-hydrate, C24H38N3O7P·C3H8O·0.122H2O, (II), and the ethanol monosolvate 0.076-hydrate, C24H38N3O7P·C2H6O·0.076H2O, (III). The crystals of (II) and (III) are isomorphous but differ in the type of solvent. The phosphono group is linked directly to the last Cαatom in the main chain for all three peptides. All the amino acids aretranslinked in the main chains. The crystal structures exhibit no intramolecular hydrogen bonds and are stabilized by intermolecular hydrogen bonds only.

De novo design of α,β-didehydrophenylalanine containing peptides: from models to applications

The de novo design of peptides and proteins has emerged as an approach for investigating protein structure and function. The success relies heavily on the ability to design relatively short peptides that can adopt stable secondary structures. To this end, substitution with α,β-dehydroamino acids, especially α,β-didehydrophenylalanine (ΔPhe or ΔF) has blossomed in manifold directions, providing a rich diversity of well-defined structural motifs. Introduction of α,β-didehydrophenylalanine induces β-bends in small and 3(10)-helices in longer peptide sequences. Most favorable conformation of ΔF residues are (φ,ψ) ∼(60°, 30°), (-60°, -30°), (-60°, 150°), and (60°, -150°). These features have been exploited in designing helix-turn-helix, helical bundle arrangements, and glycine zipper type super secondary structural motifs. The unusual capability of α,β-didehydrophenylalanine ring to form a variety of multicentered interactions (N-H…O, C-H…O, C-H…π, and N-H…π) suggests its possible exploitation for future de novo design of supramolecular structures. This work has now been extended to the de novo design of peptides with antibiotic, antifibrillization activity, etc. More recently, self-assembling properties of small dehydropeptides have been explored. This review focuses primarily on the structural and functional behavior of α,β-didehydrophenylalanine containing peptides.

Two pentadehydropeptides with different configurations of the DeltaPhe residues

Comparison of the crystal structures of two pentadehydropeptides containing DeltaPhe residues, namely (Z,Z)-N-(tert-butoxycarbonyl)glycyl-alpha,beta-phenylalanylglycyl-alpha,beta-phenylalanylglycine (or Boc(0)-Gly(1)-Delta(Z)Phe(2)-Gly(3)-Delta(Z)Phe(4)-Gly(5)-OH) methanol solvate, C(29)H(33)N(5)O(8) x CH(4)O, (I), and (E,E)-N-(tert-butoxycarbonyl)glycyl-alpha,beta-phenylalanylglycyl-alpha,beta-phenylalanylglycine (or Boc(0)-Gly(1)-Delta(E)Phe(2)-Gly(3)-Delta(E)Phe(4)-Gly(5)-OH), C(29)H(33)N(5)O(8), (II), indicates that the Delta(Z)Phe residue is a more effective inducer of folded structures than the Delta(E)Phe residue. The values of the torsion angles phi and psi show the presence of two type-III' beta-turns at the Delta(Z)Phe residues and one type-II beta-turn at the Delta(E)Phe residue. All amino acids are linked trans to each other in both peptides. Beta-turns present in the peptides are stabilized by intramolecular 4-->1 hydrogen bonds. Molecules in both structures form two-dimensional hydrogen-bond networks parallel to the (100) plane.

De novo Design of ?F -containing Heme-binding Peptides

The structural characterization of de novo designed metalloproteins together with determination of chemical reactivity can provide a detailed understanding of the relationship between protein structure and functional properties. Toward this goal, using the basic scaffold of 1pbz (Rosenblatt et al. (2003) Proc Natl Acad Sci U S A;100:13140) we have designed cyclic DeltaF-containing heme-binding peptides. The alpha- and beta-bands in UV-Vis spectroscopy are indicative of bis-His-ligated heme complex. Most of our DeltaF-containing peptides have more affinity to cobalt(III)Coproporphyrinate-I than heme because cobalt(III)Coproporphyrinate-I contains two additional propionate groups which can have salt bridge interactions with the lysine residues in the peptide. Helicity induction in peptide by DeltaF and aromatic interaction of DeltaF with heme have increased the heme affinity of CP-6-12pbz (cyclic peptide with substitutions of Ala at positions 6 and 12 by DeltaF; 905/mm) compared with 1pbz (279/mm). The nuclear magnetic resonance spectra are indicative of overall helical structure for CP-6-12pbz and CP-6-12pbz in complex with cobalt (III)Coproporphyrinate-I. The descending order of heme affinity in peptides (CP-6-12pbz > CP-12pbz > CP-5-12pbz) indicates that DeltaF at i + 3 or i - 3 from the central H9 favors heme binding but disrupts the same when placed at i - 4.

Thermal Stability of Dehydrophenylalanine-Containing Model Peptides as Probed by Infrared Spectroscopy: a Case Study of anα-Helical and a310-Helical Peptide

The temperature-dependent secondary-structural changes in the two known helical model peptides Boc-Val-deltaPhe-Ala-Leu-Gly-OMe (1; alpha-helical) and Boc-Leu-Phe-Ala-deltaPhe-Leu-OMe (2; 3(10)-helical), which both comprise a single dehydrophenylalanine (deltaPhe) residue, were investigated by means of FT-IR spectroscopy (peptide film on KBr). Both the first-order and the better-resolved second-order derivative IR spectra of 1 and 2 were analyzed. The nu(NH) (3240-3340 cm(-1)), the Amide-I (1600-1700 cm(-1)), and the Amide-II (1510-1580 cm(-1)) regions of 1 and 2 showed significant differences in thermal-denaturation experiments (22 degrees --> 144 degrees), with the 3(10)-helical peptide (2) being considerably more stable. This observation was rationalized by different patterns and strengths of intramolecular H-bonds, and was qualitatively related to the different geometries of the peptides. Also, a fair degree of residual secondary-structural elements were found even in the 'denatured' states above 104 degrees (1) or 134 degrees (2).

IR investigation on dehydrophenylalanine containing model peptides in helical conformation deposited on a crystal surface

Fourier transform ir spectra have been recorded for three 3(10)-helical and one alpha-helical pentapeptides containing dehydrophenylalanine, in a thin solid film, in order to find marker bands for various secondary structures encountered in peptides containing dehydroaminoacids. The peptide solutions were deposited and dried as thin film on zinc selenide crystal surface. This convenient sampling method has provided reliable estimates of peptide secondary structure in solid state. Detailed vibrational assignments in the spectral region between 1200-1700 cm(-1) are reported. In this region, peptide amide I, II, and III vibrations occur. Spectra-structure correlation has been presented based on the amide modes. Comparison of the ir spectra with available crystal structure data provides qualitative support for assignments of ir bands to 3(10)-helical structure and alpha-helical structure in dehydrophenylalanine containing pentapeptides. Band frequency assignments for 3(10)-helical conformation are consistent for all three peptides. All the assignments agree closely with the theoretical predictions. The spectral differences between 3(10)-helical peptides and the alpha-helical peptide have been highlighted. These findings demonstrate that a method based on ir spectroscopy can be developed for a useful approximation of three-dimensional structure of dehydropeptides in solid state. Copyright 1999 John Wiley & Sons, Inc.

Design of peptides with alpha,beta-dehydro-residues: synthesis, and crystal and molecular structure of a 3(10)-helical tetrapeptide Boc-L-Val-deltaPhe-deltaPhe-L-Ile-OCH3

The peptide Boc-L-Val-deltaPhe-deltaPhe-L-Ile-OCH3 was synthesized using the azlactone method in the solution phase, and its crystal and molecular structures were determined by X-ray diffraction. Single crystals were grown by slow evaporation from solution in methanol at 25 degrees C. The crystals belong to an orthorhombic space group P2(1)2(1)2(1) with a = 12.882(7) A, b = 15.430(5) A, c = 18.330(5) A and Z = 4. The structure was determined by direct methods and refined by a least-squares procedure to an R-value of 0.073. The peptide adopts a right-handed 3(10)-helical conformation with backbone torsion angles: phi1 = 56.0(6)degrees, psi1 = -38.0(6)degrees, phi2 = -53.8(6)degrees, psi2 = 23.6(6)degrees, phi3 = -82.9(6)degrees, psi3 = -10.6(7)degrees, phi4 = 124.9(5)degrees. All the peptide bonds are trans. The conformation is stabilized by intramolecular 4-->1 hydrogen bonds involving Boc carbonyl oxygen and NH of deltaPhe3 and CO of Val1 and NH of Ile4. It is noteworthy that the two other chemically very similar peptides: Boc-Val-deltaPhe-deltaPhe-Ala-OCH3 (i) and Boc-Val-deltaPhe-deltaPhe-Val-OCH3 (ii) with differences only at the fourth position have been found to adopt folded conformations with two overlapping beta-turns of types II and III', respectively, whereas the present peptide adopts two overlapping beta-turns of type III. Thus the introduction of Ile at fourth position in a sequence Val-deltaPhe-deltaPhe-X results in the formation of a 3(10)-helix. The crystal structure is stabilized by intermolecular hydrogen bonds involving NH of Val1 and carbonyl oxygen of a symmetry related (-x, y - 1/2, 1/2 + z) deltaPhe2 and NH of deltaPhe2 with carbonyl oxygen of a symmetry related (x, y1/2, 1/2 + z) Ile4. This gives rise to long columns of helical molecules linked head to tail running along [010] direction.

Crystal structure of Boc-LAla-deltaPhe-deltaPhe-deltaPhe-deltaPhe-NHMe: a left-handed helical peptide

Alpha,beta-dehydrophenylalanine residues constrain the peptide backbone to beta-bend conformation. A pentapeptide containing four consecutive (deltaPhe) residues has been synthesised and crystallised. The peptide Boc-LAla-deltaPhe-deltaPhe-deltaPhe-deltaPhe+ ++-NHMe (C45H46N6O7, MW = 782.86) was crystallised from an acetonitrile/methanol mixture. The crystal belongs to the orthorhombic space group P2(1)2(1)2(1) with a = 19.455(6), b = 20.912(9), c = 11.455(4) A and Z = 4. The X-ray (MoKalpha, lambda = 0.7107 A) intensity data were collected using the Rigaku-AFC7 diffractrometer. The crystal structure was determined by direct methods and refined using the least-squares technique, R = 8.41% for 1827 reflections with absolute value of Fo > 4sigma(absolute value of Fo). The molecule contains the largest stretch of consecutive dehydrophenylalanine residues whose crystal structure has been determined so far. The peptide adopts left-handed 3(10)-helical conformation despite the presence of LAla at the N-terminus. The mean phi, psi values, averaged across the last four residues are 56.8 degrees and 17.5 degrees, respectively. There are four 4-->1 intramolecular hydrogen bonds, characteristic of the 310-helix. In the crystal each molecule interacts with four crystallographically symmetric molecules with one hydrogen bond each.

Design of peptides with alpha,beta-dehydro residues: synthesis, crystal structure and molecular conformation of N-Boc-L-Ile-deltaPhe-L-Trp-OCH3

The dehydro-peptide Boc-L-Ile-deltaPhe-L-Trp-OCH3 was synthesized by the azlactone method in the solution phase. The peptide was crystallized from methanol in an orthorhombic space group P2(1)2(1)2(1)with a = 10.777(2), b = 11.224(2), c = 26.627(10) A. The structure was determined by direct methods and refined to an R value of 0.069 for 3093 observed reflections [I > or = 2delta(I)]. The peptide failed to adopt a folded conformation with backbone torsion angles: phi1 = 90.8(8)degrees, psi1 = -151.6(6)degrees, phi2 = 89.0(8)degrees, psi2 = 15.9(9)degrees, phi3 = 165.7(7)degrees, psi3T = -166.0(7)degrees . A general rule derived from earlier studies indicates that a three-peptide unit sequence with a deltaPhe at the (i + 2) position adopts a beta-turn II conformation. Because the branched beta-carbon residues such as valine and isoleucine have strong conformational preferences, they combine with the deltaPhe residue differently to generate a unique set of conformations in such peptides. The presence of beta-branched residues simultaneously at both (i + 1) and (i + 3) positions induces unfolded conformations in tetrapeptides, but a beta-branched residue substituted only at (i + 3) position can not prevent the formation of a folded beta-turn II conformation. On the other hand, the present structure shows that a beta-branched residue substituted at the (i + 1) position prevents the formation of a beta-turn II conformation. These observations indicate that a beta-branched residue at the (i + 1) position prevents a folded conformation whereas it cannot generate the same degree of effect from the (i + 3) position. This may be because of the trans disposition of the planar deltaPhe side-chain with respect to the C=O group in the residue. The molecules are packed in an anti-parallel manner to generate N2-H2...O2 (-x, y -1/2, -z + 3/2) and N3epsilon1-H3epsilon1 ...O1(-X, y -1/2, -z + 3/2) hydrogen bonds.

Design of specific structures using alpha,beta-dehydro-phenylalanine residues: synthesis, crystal structure, and molecular conformation of Boc-L-Val-delta Phe-delta Phe-L-Val-delta Phe-delta Phe-L-Val-OCH3, a 3(10)-helical heptapeptide

The peptide design using alpha,beta-dehydro-residues has wide applications. To design an extensive 3(10)-helical conformation, a heptapeptide Boc-L-Val-delta Phe-delta Phe-L-Val-delta Phe-delta Phe-L-Val-OCH3, with a repeat of two consecutive delta Phe residues has been synthesized using an azlactone method in solution phase. This is the first design using a repeat of two consecutive delta Phe residues. It is observed that the delta Phe in a sequence of two consecutive delta Phe residues, adopts only one set of phi, psi values, i.e., +/- 60 degrees, +/- 30 degrees, thus making it a specific design tool. The peptide crystallized from its solution in a methanol-water mixture in the space group P2(1) with a = 10.159(5)A, b = 20.057(2)A, c = 14.448(3)A, beta = 99.41(2)degrees, V = 2904(2)A3. The structure has been determined by direct methods and refined to an R value of 0.048 for 5404 observed [I > or = 3 sigma(I)] reflections. The structure consists of a heptapeptide Boc-L-Val-delta Phe-delta Phe-L-Val-delta Phe-delta Phe-L-Val-OCH3 and a solvent methanol molecule in the asymmetric unit. All peptide units in the structure are trans. As a result of six overlapping type III beta-turns formed involving seven residues and five intramolecular 4-->1 hydrogen bonds, the peptide adopts a right-handed 3(10)-helical conformation with more than two complete helical turns. It is noteworthy that starting from the Boc group to the C-terminal residue of Val, the 3(10)-helical structure is maintained well. The carbonyl oxygen atom of the Boc group is the first acceptor whereas the carbonyl oxygen atom of Val4 is the last acceptor in the helical structure of the peptide. The side chains of four delta Phe residues in this helical arrangement exist in a slightly staggered arrangement. The solvent methanol molecule interacts through its hydroxyl group and forms two intermolecular hydrogen bonds, one as a donor with a C-terminal CO group of delta Phe6 and second as an acceptor with the NH group of delta Phe2 from the N-terminal region of the peptide. Thus the solvent molecule plays a significant role in promoting a head-to-tail packing of 3(10)-helices of the peptide. There are no lateral hydrogen bonds between the helices, but there exist several van der Waals interactions involving the hydrophobic side chains of peptide molecules.

Design of peptides using alpha,beta-dehydro-residues: synthesis, crystal structure and molecular conformation of Boc-L-Val-delta Phe-delta Phe-L-Val-OCH3

The peptide Boc-L-Val-delta Phe-delta Phe-L-Val-OCH3 was synthesized by the azlactone method in solution phase, and its crystal and molecular structures were determined by x-ray diffraction method. Single crystals were grown by slow evaporation from a methanol/water solution at 6 degrees C. The crystals belong to an orthorhombic space group P212121 with a = 10.478 (6) A, b = 13.953 (I), c = 24.347 (2) and Z = 4. The structure was determined by direct methods and refined by least squares procedure to an R value of 0.052. The structure consists of a peptide and a water molecule. The peptide adopts two overlapping beta-turn conformations of Types II and I' with torsion angles: phi 1 = -54.8 (6) psi 1 = 130.5 (4), phi 2 = 65.8 (5), psi 2 = 12.8 (6), phi 3 = 79.4 (5), psi 3 = 3.9 (7) degrees. The conformation is stabilized by intramolecular hydrogen bonds involving Boc CO and NH of delta Phe3 and CO of Val1 and NH of Val4. The molecules are tightly packed in the unit cell. The crystal structure is stabilized by hydrogen bonds involving NH of delta Phe2 and CO of a symmetry related (x-1/2, 1/2-y, -z) delta Phe2. The solvent-water molecule forms two hydrogen bonds with peptide molecule involving NH of Val1 as an acceptor and another with CO of a symmetry related (1-x, y-1/2, 1/2 -z) delta Phe3 as a donor. These studies indicate that a tetrapeptide with two consecutive delta Phe residues sequenced with valines on both ends adopts two overlapping beta-turns of Types II and I'.

Development of a model for the delta-opioid receptor pharmacophore. 4. Residue 3 dehydrophenylalanine analogues of Tyr-c[D-Cys-Phe-D-Pen]OH (JOM-13) confirm required gauche orientation of aromatic side chain

We have previously proposed a model for the delta-opioid receptor binding conformation of the high affinity tetrapeptide Tyr-c[D-Cys-Phe-D-Pen]OH (JOM-13) based on experimental and theoretical conformational analysis of this peptide and a correlation of conformational preferences of further conformationally restricted analogues of this tetrapeptide with their receptor binding affinities. A key element of this model is the requirement that the Phe3 side chain exist in the chi 1 = -60 degrees conformation. Conformational calculations on the residue 3 dehydrophenylalanine analogues of JOM-13 suggest that while the dehydro (Z) phenylalanine analogue can be superimposed easily with the proposed binding conformer of JOM-13, the dehydro(E)phenylalanine analogue cannot. These results lead to the prediction that the dehydro(Z)phenylalanine analogue should display similar delta-receptor binding affinity as JOM-13 while the dehydro(E)phenylalanine analogue is expected to bind less avidly. Synthesis and subsequent opioid receptor binding analysis of the dehydrophenylalanine analogues of JOM-13 confirm these predictions, lending support to the delta-pharmacophore model.

Design of peptides: synthesis, crystal structure and molecular conformation of N-Boc-L-Val-delta Phe-L-Ile-OCH3

The dehydro-peptide Boc-L-Val-delta Phe-L-Ile-OCH3 was synthesized by the azlactone method in the solution phase. The peptide crystallized from a methanol/dimethyl sulfoxide (95:5) mixture in space group P6(1) with a = b = 15.312(1), c = 22.164(5) A. The structure was determined by direct methods and refined to an R value of 0.098 for 1589 observed reflections [I > or = 1.5 sigma (I)]. The peptide adopts an S-shaped conformation with torsion angles: phi 1 = -127(1), psi 1 = -44(1), phi 2 = 67(1), psi 2 = 37(1), phi 3 = -82(1) degrees. The side-chain torsion angles in delta Phe of chi 2(1) = 1(2), chi 2(2,1) = 7(2) and chi 2(2,2) = 177(1) degrees indicate that the delta Phe residue is essentially planar. In valyl residue the two side-chain torsion angles are chi 1(1) = -65(1) and chi 1(2) = 177(1), whereas the torsion angles in Ile are chi 3(1,1) = 72(2), chi 3(1,2) = -159(2), chi 3(2) = 150(2) degrees. This is the first peptide which does not adopt a folded conformation for a sequence with a delta Phe at the (i + 2) position. The molecular packing in the crystals is stabilized by several hydrogen bonds: N1-H1-...O1 = 2.77(1) A, N2-H2...O1' = 2.95(1) A, N3-H3...O2 = 2.85(1) A and a possible weak interaction N2-H2...O2' = 3.29(1) A within the columns of molecules along the c-axis and van der Waals forces between the columns.

Design of peptides: synthesis, crystal structure and molecular conformation of N-Boc-L-Val-delta Phe-L-Val-OC H3

The dehydropeptide Boc-L-Val-delta Phe-L-Val-OC H3 was synthesized by azlactone method in solution phase. The peptide crystallized from its solution in a methanol/water mixture (70:30) in space group P2(1)2(1)2(1) with a = 13.638(1)A, b = 22.864(3)A, c = 27.600(2)A, V = 8606(1)A3. The structure was determined by direct methods and refined to an R value of 0.089 for 3326 observed [1 > or = 2 sigma(I)] reflections. The structure contains three crystallographically independent molecules. Two molecules (A and B) adopt identical conformations with phi 1(A) = -130(1), phi 1(B) = -139(1), psi 1(A) = 153(1), psi 1(B) = 145(1), phi 2(A) = 62(1), phi 2(B) = 56(1), psi 2(A) = 33(1), psi 2(B) = 33(1), phi 3(A) = -75(1), phi 3(B) = -77(1) psi 3T(A) = 152(1) and psi 3T(B) = 163(1) degrees. The conformation of the third molecule (C) is different as in that torsion angle psi 1 is rotated by 180 degrees. The backbone torsion angles are phi 1 = -128(2), psi 1 = -37(2), phi 2 = 65(1), psi 2 = 35(1), phi 3 = -84(1) and psi 3T = 169(1). It is significant that a characteristic beta-turn II conformation as observed in peptides with a delta Phe residue at (i+2) position has not been observed in this case. Thus the present structure demonstrates that an (i+2) substituted delta Phe with branched beta-carbon residue Val on both sides of it in a three peptide unit sequence does not adopt a folded conformation. The three independent molecules in the asymmetric unit form three hydrogen bonds between each pair of molecules and generates a tightly interacting unit of three molecules. These units pack into the crystalline state with hydrogen bonds involving N1, N2 and N3 of molecule C and O1' and O2' of symmetry related molecule A. The structure confirms that a peptide containing a delta Phe residue at (i+2) position with branched beta-carbon residues as its immediate neighbours on both sides does not adopt a folded conformation. This structure further demonstrates that the unfolded structures without any intramolecular hydrogen bond can be influenced by intermolecular forces, thus causing conformational variations in saturated residues. It is noteworthy that the conformation of the delta Phe residue remains unchanged in all the three molecules.

Pi-turns in proteins and peptides: Classification, conformation, occurrence, hydration and sequence

The i + 5-->i hydrogen bonded turn conformation (pi-turn) with the fifth residue adopting alpha L conformation is frequently found at the C-terminus of helices in proteins and hence is speculated to be a "helix termination signal." An analysis of the occurrence of i + 5-->i hydrogen bonded turn conformation at any general position in proteins (not specifically at the helix C-terminus), using coordinates of 228 protein crystal structures determined by X-ray crystallography to better than 2.5 A resolution is reported in this paper. Of 486 detected pi-turn conformations, 367 have the (i + 4)th residue in alpha L conformation, generally occurring at the C-terminus of alpha-helices, consistent with previous observations. However, a significant number (111) of pi-turn conformations occur with (i + 4)th residue in alpha R conformation also, generally occurring in alpha-helices as distortions either at the terminii or at the middle, a novel finding. These two sets of pi-turn conformations are referred to by the names pi alpha L and pi alpha R-turns, respectively, depending upon whether the (i + 4)th residue adopts alpha L or alpha R conformations. Four pi-turns, named pi alpha L'-turns, were noticed to be mirror images of pi alpha L-turns, and four more pi-turns, which have the (i + 4)th residue in beta conformation and denoted as pi beta-turns, occur as a part of hairpin bend connecting twisted beta-strands. Consecutive pi-turns occur, but only with pi alpha R-turns. The preference for amino acid residues is different in pi alpha L and pi alpha R-turns. However, both show a preference for Pro after the C-termini. Hydrophilic residues are preferred at positions i + 1, i + 2, and i + 3 of pi alpha L-turns, whereas positions i and i + 5 prefer hydrophobic residues. Residue i + 4 in pi alpha L-turns is mainly Gly and less often Asn. Although pi alpha R-turns generally occur as distortions in helices, their amino acid preference is different from that of helices. Poor helix formers, such as His, Tyr, and Asn, also were found to be preferred for pi alpha R-turns, whereas good helix former Ala is not preferred. pi-Turns in peptides provide a picture of the pi-turn at atomic resolution. Only nine peptide-based pi-turns are reported so far, and all of them belong to pi alpha L-turn type with an achiral residue in position i + 4. The results are of importance for structure prediction, modeling, and de novo design of proteins.

Helix termination and chain reversal: crystal and molecular structure of the alpha, beta-dehydrooctapeptide Boc-Val-DeltaPhe-Phe-Ala-Leu-Ala-DeltaPhe-Leu-OH

The crystal structure of the dehydro octapeptide Boc-Val-DeltaPhe-Phe-Ala-Leu-Ala-DeltaPhe-Leu-OH has been determined to atomic resolution by X-ray crystallographic methods. The crystals grown by slow evaporation of peptide solution in methanol/water are orthorhombic, space group P2(1)2(1)2(1). The unit cell parameters are a= 8.404(3), b= 25.598(2) and c= 27.946(3) Angstrom, Z=4. The agreement factor is R = 7.58% for 3636 reflections having (vertical bar Fo vertical bar) > or = 3sigma (vertical bar Fo vertical bar). The peptide molecule is characterised by a 3(10)-helix at the N-terminus and a pi-turn at the C-terminus. This conformation is exactly similar to the helix termination features observed in proteins. The pi-turn conformation observed in the octapeptide is in good agreement with the conformational features of pi-turns seen in some proteins. The alphaL-position in the pi-turn of the octapeptide is occupied by DeltaPhe7, which shows that even bulky residues can be accommodated in this position of the pi-turns. In proteins, it is generally seen that alphaL-position is occupied by glycine residue. No intermolecular head-to-tail hydrogen bonds are observed in solid state structure of the octapeptide. A water molecule located in the unit cell of the peptide molecule is mainly used to hold the peptide molecule together in the crystal. The conformation observed for the octapeptide might be useful to understand the helix termination and chain reversal in proteins and to construct helix terminators for denovo protein design.

Solution structure of dehydropeptides: a CD investigation

A CD investigation of eleven dehydropeptides is reported. The compounds investigated include tri-, tetra-, hepta-, and octapeptides and contain one, two, or three dehydro-phenylalanine (deltaPhe) residues. The peptides showed different CD profiles depending on chain length, position, and number of dehydro residues. The CD data very much complemented that provided by nmr studies, confirming the conformational preference for beta-bend structures in small peptides (tripeptides), and 3(10)-helical or alpha-helical structures in longer peptides. The secondary structures were stable in chloroform solution and were denatured by addition of trifluoroacetic acid. Solvent titration experiments performed by measuring CD as a function of solvent composition provided evidence that the order < or > disorder conformational changes occurred as cooperative transitions.

3(10)-Helices, helix screw sense and screw sense reversal in the dehydro-peptide Boc-Val-delta Phe-Gly-delta Phe-Val-OMe

The pentapeptide Boc-Val-delta Phe-Gly-delta Phe-Val-OME, containing two dehydro-phenylalanine (delta Phe) residues, has been synthesized and its structure investigated. In the crystalline state, the molecule adopts a right-handed 3(10)-helical conformation stabilized by two intramolecular hydrogen bonds between CO of Val1 and NH of delta Phe4, and between CO of delta Phe2 and NH of Val5, respectively. NMR measurements are consistent with the presence of 3(10)-helical structures also in acetonitrile and dimethylsulphoxide solution: the distances between backbone protons estimated from NOE connectivities are in overall agreement with those observed in the solid state; the chemical shifts of the amide protons show the smaller temperature coefficients for the NHs that in solid state are involved in intramolecular hydrogen bonds. The CD spectra in acetonitrile, chloroform, methanol and dimethylsulphoxide display exciton couplets of bands corresponding to the delta Phe electronic transition at 280 nm; the sign of the bands is consistent with the presence of helical structures having a prevalent left-handed screw sense. Addition of 1,1,1,3,3,3-hexafluoro-propan-2-ol gives rise to the gradual appearance of a couplet of opposite sign, suggesting the helix reversal from left-handed sense to right-handed sense. The conformational behaviour is discussed on the basis of the specific sequence of the peptide.

Crystal and molecular structure of Boc-Phe-Val-OMe; comparison of the peptide conformation with its dehydro analogue

The crystal structure of the peptide Boc-Phe-Val-OMe determined by X-ray diffraction methods is reported in this paper. The crystals grown from aqueous methanol are orthorhombic, space group P2(1)2(1)2(1),a = 11.843(2), b = 21.493(4), c = 26.676(4) A3 and V = 6790 A3. Data were collected on a CAD4 diffractometer using MoK alpha radiation (lambda = 0.7107 A) up to Bragg angle theta = 26 degrees. The structure was solved by direct methods and refined by a least-squares procedure to an R value of 6.8% for 3288 observed reflections. There are three crystal-lographically independent peptide molecules in the asymmetric unit. All the three molecules exhibit extended conformation. The sidechain of the Val2 residue shows two different conformations. The conformation of the peptide Boc-Phe-Val-OMe is compared with the conformation of Ac-delta Phe-Val-OH. It is observed that while Boc-Phe-Val-OMe exhibits an extended conformation, Ac-delta Phe-Val-OH shows a folded conformation. The results of this comparison highlight the conformation constraining property of the delta Phe residue. Interestingly, even though Boc-Phe-Val-OMe and Ac-delta Phe-Val-OH are conformationally different, they exhibit similar packing patterns in the solid state.