Alpha-beta-dehydro-amino acid residues in the design of peptide structures. Molecular and crystal structures of two folded dehydro peptides

Non-Canonical Amino Acids as Building Blocks for Peptidomimetics: Structure, Function, and Applications

This review provides a fresh overview of non-canonical amino acids and their applications in the design of peptidomimetics. Non-canonical amino acids appear widely distributed in nature and are known to enhance the stability of specific secondary structures and/or biological function. Contrary to the ubiquitous DNA-encoded amino acids, the structure and function of these residues are not fully understood. Here, results from experimental and molecular modelling approaches are gathered to classify several classes of non-canonical amino acids according to their ability to induce specific secondary structures yielding different biological functions and improved stability. Regarding side-chain modifications, symmetrical and asymmetrical α,α-dialkyl glycines, Cα to Cα cyclized amino acids, proline analogues, β-substituted amino acids, and α,β-dehydro amino acids are some of the non-canonical representatives addressed. Backbone modifications were also examined, especially those that result in retro-inverso peptidomimetics and depsipeptides. All this knowledge has an important application in the field of peptidomimetics, which is in continuous progress and promises to deliver new biologically active molecules and new materials in the near future.

Conformation of dehydropentapeptides containing four achiral amino acid residues - controlling the role of L-valine

Structural studies of pentapeptides containing an achiral block, built from two dehydroamino acid residues (Δ^ZPhe and ΔAla) and two glycines, as well as one chiral L-Val residue were performed using NMR spectroscopy. The key role of the L-Val residue in the generation of the secondary structure of peptides is discussed. The obtained results suggest that the strongest influence on the conformation of peptides arises from a valine residue inserted at the C-terminal position. The most ordered conformation was found for peptide Boc-Gly-ΔAla-Gly-Δ^ZPhe-Val-OMe (3), which adopts a right-handed helical conformation.

Effects of side-chain orientation on the backbone conformation of the dehydrophenylalanine residue. Theoretical and X-ray study

Two E isomers of α,β-dehydro-phenylalanine, Ac-(E)-ΔPhe-NHMe (1a) and Ac-(E)-ΔPhe-NMe(2) (2a), have been synthesized and their low temperature structures determined by single-crystal X-ray diffraction. A systematic theoretical analysis was performed on these molecules and their Z isomers (1b and 2b). The ϕ,ψ potential energy surfaces were calculated at the MP2/6-31+G(d,p) and B3LYP/6-31+G(d,p) levels in the gas phase and at the B3LYP/6-31+G(d,p) level in the chloroform and water solutions with the SCRF-PCM method. All minima were fully optimized by the MP2 and DFT methods, and their relative stabilities were analyzed in terms of π-conjugation, internal H-bonds, and dipole-dipole interactions between carbonyl groups. The results indicate that all the studied compounds can adopt the conformation H (ϕ, ψ ≈ ±40°, ∓120°) which is atypical for standard amino acids residues. A different arrangement of the side chain in the E and Z isomers causes them to have different conformational preferences. In the presence of a polar solvent both Z isomers of ΔPhe (1b and 2b) are found to adopt the 3(10)-helical conformation (left- and right-handed are equally likely). On the other hand, this conformation is not accessible or highly energetic for E isomers of ΔPhe (1a and 2a). Those isomers have an intrinsic inclination to have an extended conformation. The conformational space of the Z isomers is much more restricted than that of the E derivative both in the gas phase and in solution. In the gas phase the E isomers of ΔPhe have lower energies than the Z ones, but in the aqueous solution the energy order is reversed.

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.

Observation of glycine zipper and unanticipated occurrence of ambidextrous helices in the crystal structure of a chiral undecapeptide

Background

The de novo design of peptides and proteins has recently surfaced as an approach for investigating protein structure and function. This approach vitally tests our knowledge of protein folding and function, while also laying the groundwork for the fabrication of proteins with properties not precedented in nature. The success of these studies relies heavily on the ability to design relatively short peptides that can espouse stable secondary structures. To this end, substitution with α, β-dehydroamino acids, especially α, β-dehydrophenylalanine (ΔPhe) comes in use for spawning well-defined structural motifs. Introduction of ΔPhe induces β-bends in small and 3₁₀-helices in longer peptide sequences.

Results

The present report is an investigation of the effect of incorporating two glycines in the middle of a ΔPhe containing undecapeptide. A de novo designed undecapeptide, Ac-Gly¹-Ala²-ΔPhe³-Leu⁴-Gly⁵-ΔPhe⁶-Leu⁷-Gly⁸-ΔPhe⁹-Ala¹⁰-Gly¹¹-NH₂, was synthesized and characterized using X-ray diffraction and Circular Dichroism spectroscopic methods. Crystallographic studies suggest that, despite the presence of L-amino acid (L-Ala and L-Leu) residues in the middle of the sequence, the peptide adopts a 3₁₀-helical conformation of ambidextrous screw sense, one of them a left-handed (A) and the other a right-handed (B) 3₁₀-helix with A and B being antiparallel to each other. However, CD studies reveal that the undecapeptide exclusively adopts a right-handed 3₁₀-helical conformation. In the crystal packing, three different interhelical interfaces, Leu-Leu, Gly-Gly and ΔPhe-ΔPhe are observed between the helices A and B. A network of C-H...O hydrogen bonds are observed at ΔPhe-ΔPhe and Gly-Gly interhelical interfaces. An important feature observed is the occurrence of glycine zipper motif at Gly-Gly interface. At this interface, the geometric pattern of interhelical interactions seems to resemble those observed between helices in transmembrane (TM) proteins.

Conclusion

The present design strategy can thus be exploited in future work on de novo design of helical bundles of higher order and compaction utilizing ΔPhe residues along with GXXG motif.

Computational analysis of the autocatalytic posttranslational cyclization observed in histidine ammonia-lyase. A comparison with green fluorescent protein

Density functional calculations using hybrid functionals (B3LYP) have been performed to study the mechanism of the autocatalytic posttranslational cyclization observed in histidine ammonia-lyase. Two mechanisms were analyzed, the commonly accepted mechanism in which cyclization precedes dehydrogenation (reduced mechanism) and a mechanism in which dehydrogenation precedes cyclization (oxidized mechanism). The reduced pathway is not supported by the calculations, while the alternative oxidized mechanism where a dehydration occurs prior to the formation of the ring yields reasonable energetics for the system. Database searches showed that the oxidative mechanism in which the formation of the dehydro amino acids in residue i + 1 precedes the cyclization is also structurally advantageous as it results in shorter distances between the carbonyl carbon of residue i and the amide nitrogen of residue i + 2 and, therefore, preorganizes the protein for cyclization. Conformational searches showed that these distances were also unusually short and exhibited very little variation in the Delta-Ala143 HAL tetramer, indicating that like GFP the tetrameric form of HAL is rigidly preorganized for cyclization. The monomeric form of HAL is less preorganized than the tetrameric form of HAL. Dehydro amino acids aid in the preorganization, but the main driving force in the rigid tight turn formation is the influence of the surrounding protein.

beta-Turned dipeptoids as potent and selective CCK(1) receptor antagonists

To improve our knowledge of the bioactive conformation of CCK(1) antagonists, we previously described that replacement of the alpha-MeTrp residue of dipeptoids with the (2S,5S, 11bR)-2-amino-3-oxohexahydroindolizino[8,7-b]indole-5-carbox ylate (IBTM) skeleton, a probed type II' beta-turn mimetic, led to restricted analogues (2S,5S,11bR,1'S)- and (2S,5S,11bR, 1'R)-2-(benzyloxycarbonyl)amino-5-[1'-benzyl-2'-(carboxy)ethyl]carbam oyl-3-oxo-2,3,5,6,11,11b-hexahydro-1H-indolizino[8,7-b]indole, 1a,b, showing high binding affinity and selectivity for CCK(1) receptors. In this report, we describe the synthesis and binding profile of new analogues of compounds 1 designed to explore the importance of the C-terminal residue and of the type of beta-turn on the receptor binding affinity and selectivity. Structure-affinity relationship studies show that a C-terminal free carboxylic acid and an S configuration of the Phe and betaHph residues are favorable for CCK(1) receptor recognition. Moreover, selectivity for this receptor subtype is critically affected by the beta-turn type. Thus, while compounds 15a and 16a, containing the (2S,5S,11bR)- and (2R,5R, 11bS)-IBTM frameworks, respectively, are both endowed with nanomolar affinity for CCK(1) receptors, restricted dipeptoid derivative 15a, incorporating the type II' IBTM mimetic, shows approximately 6-fold higher CCK(1) selectivity than analogue 16a, with the type II mimetic. From these results, we propose that the presence of a beta-turn-like conformation within the peptide backbone of dipeptoids could contribute to their bioactive conformation at the CCK(1) receptor subtype. Concerning functional activity, compounds 15a and 16a behave as CCK(1) receptor antagonists.

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.

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.

On the potential role of the amino nitrogen atom as a hydrogen bond acceptor in macromolecules

Crystallographic studies of duplex DNA have indicated that opposing exocyclic amino groups may form close NH⋯:N contacts. To study the nature of such interactions, we have examined the database of small molecule, high-resolution crystal structures for more accurate examples of this type of unconventional interaction. We have found cases where the amino groups in guanine and adenine bases accept hydrogen bonds from conventional donors, such as amino or hydroxyl groups. More frequently, the purine amino group was found to contact closely electropositive C-H groups. Searches of the nucleic acid structural databases also yielded several examples where the purine amino group is contacted by hydrogen bond donors in macromolecules. Ab initio calculations indicate that the hydrogen-amino contact is improved energetically when the amino group moves from the conventional geometry, where all atoms are co-planar with the base, to one in which the hydrogen atoms lie out of the plane and the nitrogen is at the apex of a pyramid, resulting in polarization of the amino group. The combined structural and theoretical data suggest that the amino group is flexible, and can accommodate close contacts, because the resulting polarization permits electropositive atoms to approach the amino group nitrogen more closely than expected for their conventional van der Waals radii. The flexibility of the amino group may permit particular DNA conformations that enforce hydrogen-amino contacts to optimize favorable stacking interactions, and it may play a role in the recognition of nucleosides. We speculate that the amino group can accept hydrogen bonds under special circumstances in macromolecules, and that this ability might play a mechanistic role in catalytic processes such as deamination or amino transfer.

Aza-peptides. III. Experimental structural analysis of aza-alanine and aza-asparagine-containing peptides

To determine the structural perturbations induced by the C alpha H-->N alpha exchange in aza-peptides, we have examined by 1H NMR and IR spectroscopy various derivatives of the aza-analogues of alanine, aspartic acid and asparagine in different organic solvents with increasing polarity. Their general formulas are: R1-AzXaa-NR2R3, R1-Pro-AzXaa-NR2R3 and R1-AzXaa-Pro-NR2R3 (where AzXaa denotes the aza-analogue of the amino acid residue Xaa = Ala, Asp, Asn; R1 = Boc, Z; R2, R3 = H, Me, iPr). The aza-analogue of an amino acid residue appears to be a strong beta-turn-inducing motif, and the AzAsn carboxamide side-chain is capable of interacting, as a proton donor, with the preceding peptide carbonyl group.

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.

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.

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

alpha,beta-Dehydro amino acid residues are known to constrain the peptide backbone to the beta-bend conformation. A pentapeptide containing only one alpha,beta-dehydrophenylalanine (delta Phe) residue has been synthesized and crystallized, and its solid state conformation has been determined. The pentapeptide Boc-Leu-Phe-Ala-delta Phe-Leu-OMe (C39H55N5O8, Mw = 721.9) was crystallized from aqueous methanol. Monoclinic space group was P2(1), a = 10.290(2) degrees, b = 17.149(2) degrees, c = 12.179(2) A, beta = 96.64(1) degrees with two molecules in the unit cell. The x-ray (MoK alpha, lambda = 0.7107A) intensity data were collected using a CAD4 diffractometer. The crystal structure was determined by direct methods and refined using least-squares technique. R = 4.4% and Rw = 5.4% for 4403 reflections having magnitude of F0 > or = 3 sigma(magnitude of F0). All the peptide links are trans and the pentapeptide molecule assumes 3(10)-helical conformation. The mean phi,psi values, averaged over the first four residues, are -64.4 degrees, -22.4 degrees respectively. There are three 4-->1 intramolecular hydrogen bonds, characteristic of 3(10)-helix. In the crystal, the peptide helices interact through two head-to-tail, N-H-O intermolecular hydrogen bonds. The peptide molecules related by 2(1) screw symmetry form a skewed assembly of helices.

Conformational investigation of alpha, beta-dehydropeptides. Part VI. Molecular and crystal structure of benzyloxycarbonylglycyl-(Z)-dehydrophenylalanine

The structure of a peptide containing C-terminal dehydrophenylalanine, Z-Gly-(Z)-delta Phe (C19H18N2O5, MW = 354) was determined from single-crystal X-ray diffraction data. Needle-shaped crystals were grown from a 1:1 mixture of methanol-acetone in the monoclinic space group P2(1) with a = 14.717(4), b = 4.941(2), c = 12.073(4) A, beta = 103.72(4) degrees; V = 852.86(8) A3, Z = 2 and Dc = 1.32 g cm-3. The structure was solved by direct methods using SHELXS-86 and refined to a final R-index of 0.032 for 1714 observed reflections. The peptide adopts a conformation folded at the glycine residue, and principal torsion angles are omega 0 = -167.6(2) degrees, phi 1 = -71.8(3) degrees, psi 1 = -31.6(4) degrees, omega 1 = -165.7(3) degrees, phi 2 = 65.6(4) degrees, psi 1(2) = -174.4(3) degrees and psi 2(2) = 5.2(4) degrees. Two intermolecular hydrogen bonds, N1-H...O0' and O2-H...O1', join the folded molecules into columns and link columns to each other, respectively. FTIR spectroscopy shows the presence of three hydrogen bonds. This third one has been interpreted as an intramolecular hydrogen bond of the N2-H...N1 type.

alpha,beta-Dehydro-amino acid residues in the design of peptide structures: synthesis, crystal structure, and molecular conformation of two homologous peptides-N-Ac-dehydro-Phe-L-Leu-OCH3 and N-Ac-dehydro-Phe-NorVal-OCH3

The dehydro-residue containing peptides N-Ac-dehydro-Phe-L-Leu-OCH3 (I) and N-Ac-dehydro-Phe-NorVal-OCH3 (II) were synthesized by the usual workup procedures. The peptides crystallize from their solutions in methanol in space group P6(5): (I) a = b = 12.528(2) A, c = 21.653(5) A; (II) a = b = 12.532(2) A, c = 21.695(4) A. The structures were determined by direct methods. Both peptides adopt similar conformations with phi,psi of dehydro-Phe as follows: (I) -57.0(5) degrees and -37.0(5) degrees; (II) -56.0(5), degrees, and -37.5(5) degrees. The observed data on dehydro-Phe when placed at the (i + 1) position show that the phi,psi values of dehydro-Phe are either -60 degrees, 140 degrees or -60 degrees, -30 degrees. The conformation of -60 degrees, 140 degrees can be accommodated only with a flexible residue at the (i + 2) position while the phi,psi values of -60 degrees, -30 degrees are obtained with a bulky residue at the (i + 2) position as in the present structures. The molecules are packed in a helical way along the c axis. These are held by two strong intermolecular hydrogen bonds involving both NH as donors and acetyl group and dehydro-Phe oxygen atoms as acceptors.

Solid state and solution structure of Boc-L-Ala-delta Phe-delta Phe-NHMe: a dehydropeptide showing propensity for 3(10)-helices of both screw senses

The crystal and molecular structure of the peptide Boc-L-Ala-delta Phe-delta Phe-NHMe, containing two consecutive dehydro-phenylalanine (delta Phe) residues, has been solved by x-ray diffraction. Two independent molecules, X and Y, are present in the crystallographic unit. Their conformation corresponds approximately to an incipient 3(10)-helix stabilized by two intramolecular hydrogen bonds. The (phi, psi) torsion angles, however, have negative and positive signs in the two molecules X and Y, respectively. Therefore, in spite of the presence of an amino acid residue of the L configuration, the two helical molecules have opposite screw senses, even though the right-handed helix is less distorted than the left-handed one in correspondence of the L-Ala residue. The CD spectra in various solvents exhibit exciton bands originating from dipole-dipole interaction between the delta Phe side chains. Addition of DMSO to the chloroform solution produces, as a first step, a strong increasing of the CD bands, which are then progressively canceled by increasing DMSO concentration. The nmr data parallel the behavior observed in the CD spectra. In CDCl3 solution, the temperature coefficients of the NH resonances are consistent with the involvement of the last two amide protons of the sequence in intramolecular hydrogen bonds, but only negligibly small nuclear Overhauser effects (NOE) are observed. Addition of 5% DMSO-d6 allows the observation of diagnostic NOEs. CD and nmr data indicate that the solid state structure is retained in solution, and are consistent with the presence of right-handed and left-handed conformers, with a prevalence of the more stable right-handed one.

X-ray crystallography of peptides: the contributions of the Italian laboratories

The review article summarizes the most relevant solid state structural and conformational results obtained in the laboratories involved in Italy in the studies of synthetic and natural peptides by x-ray diffraction analyses. Some of the topics will include research studies carried out in other European countries, whereas in other cases studies carried out in Italy will be included in other review articles included in this volume. The review deals with peptides containing symmetrically achiral and unsymmetrically chiral C alpha,alpha-dialkylated glycine residues, peptides containing beta-alanine residues, alpha,beta-dehydroamino acid residues, and aminosuccinyl residues, peptides containing the thioamide surrogate, heterochiral peptides and several bioactive peptides systems with the proposed relationships between function and structure.

Conformational characteristics of peptides containing alpha, beta-dehydroamino acid residues

The structural preferences of synthetic peptides containing alpha, beta-dehydroamino acid residues, as determined by theoretical studies, x-ray diffraction analyses, and spectroscopic studies, are reviewed. The role of delta ZPhe residues in stabilizing type II beta-turn structures in small peptides and in nucleating helical structure in longer peptides is exemplified by several crystal as well as solution structural studies. From the few studies reported so far it appears that delta ZLeu influences the peptide backbone, much like the delta ZPhe residue, whereas delta Ala prefers the extended conformation, suggesting that the nature of beta substituents might influence the conformation restriction behavior of the dehydroresidues. Conformational studies on synthetic peptides containing delta E, delta ZAbu, and delta Val have also been described.