Hybrid peptide hairpins containing alpha- and omega-amino acids: conformational analysis of decapeptides with unsubstituted beta-, gamma-, and delta-residues at positions 3 and 8

α,ε-Hybrid Peptide-Stabilized Magnetic Nanoparticle-Coated Paper-Based Actuators

The development of α,ε-hybrid peptide-stabilized magnetic nanoparticles and their application to fabricate a paper-based actuator has been reported. From single-crystal diffraction analysis, the nitropeptide 2 has an extended structure with a trans geometry. The one-pot in situ multiple oxidation-reduction reaction of a synthetic nitropeptide solution in ammonium hydroxide and FeCl₂ leads to the formation of Fe₃O₄ nanoparticles. The reduction reaction replaces the nitro group with an amine group, which finally acts as capping agent for the stabilization of the Fe₃O₄ nanoparticles. Paper-based soft magneto machines with multivariant actuation modes such as contraction-expansion, bending, and uplifting locomotion have been studied. The device has potential as controllable paper-based soft robots.

Conformational Heterogeneity and Self-Assembly of α,β,γ-Hybrid Peptides Containing Fenamic Acid: Multistimuli-Responsive Phase-Selective Gelation

The effect of fenamic acid-α-aminoisobutyric acid corner motif in α,β,γ-hybrid peptides has been reported. From X-ray single-crystal diffraction studies, it is observed that Phe-containing peptide 1 has an "S"-shaped conformation that is stabilized by two consecutive intramolecular N-H···N hydrogen bonds. However, the tyrosine analogue peptide 2 has an "S"-shaped conformation, which is stabilized by consecutive intramolecular six-member N-H···N and seven-member N-H···O hydrogen bonds. The asymmetric unit of peptide 3 containing m-aminobenzoic acid has two molecules which are stabilized by multiple intermolecular hydrogen-bonding interactions. There are also π-π stacking interactions between the aromatic rings of fenamic acid. The peptides 1 and 2 have a polydisperse microsphere morphology, but peptide 3 has an entangled fiber-like morphology. Peptides 1-3 do not form organogels. However, in the presence of water, the peptide 3 forms a phase-selective instant gel in xylene. The gel exhibits high stability and thermal reversibility. The phase-selective gel of peptide 3 is highly responsive to H₂SO₄.

α,ε-Hybrid Peptide Foldamers: Self-Assembly of Peptide with Trans Carbon-Carbon Double Bonds in the Backbone and Its Saturated Analogue

The effect of geometrically rigid trans α,β-unsaturated ε-amino acids on the structure, folding, and assembly of α,ε-hybrid peptide foldamers has been reported. From single-crystal diffraction analysis, the unsaturated tetrapeptide 1 has stapler-pin-like structure but without intramolecular hydrogen bond. The asymmetric unit has two molecules that are stabilized by multiple intermolecular hydrogen bonding interactions as well as π-π stacking interactions between the aromatic rings of 3-aminocinnamic acid. Peptide 1 does not form organogel. But on hydrogenation, peptide 1 provides the saturated α,ε-hybrid peptide foldamer 2, which forms instant gel in most of the aromatic solvents. The gel exhibits high stability. The unsaturated peptide 1 has porous microsphere morphology, but saturated analogue 2 has ribbonlike morphology. The gel has been used efficiently for removal of cationic organic pollutants from waste water.

Effect of methylene group insertions on the structural rigidity of Aib containing helices

Nonprotein amino acids are being extensively used in the design of synthetic peptides to create new structure mimics. In this study we report the effect of methylene group insertions in a heptapeptide Boc-Ala1-Leu2-Aib3-Xxx4-Ala5-Leu6-Aib7-OMe which nicely folds into a mixed 310 -/α-helical structure when Xxx= Ala. Analogs of this peptide have been made and studied by replacing central Xxx4 residue with Glycine (α-residue), β-Alanine (β-Αla), γ-aminobutyric acid (Gaba), and ε-aminocaproic acid (ε-Aca). NMR and circular dichroism were used to study the solution structure of these peptides. Crystals of the peptides containing alanine, β-Αla, and Gaba reveal that increasing the number of central methylene (-CH2 -) groups introduces local perturbations even as the helical structure is retained.

Venkatesha M, Balaram P. Structural characterization of folded and extended conformations in peptides containing γ amino acids with proteinogenic side chains: crystal structures of γn, (αγ)n and γγδγ sequences

γ_n amino acid residues can be incorporated into structures in γ_n and hybrid sequences containing folded and extended α and δ residues.

Unusual folding propensity of an unsubstituted β,γ-hybrid model peptide: importance of the C-H⋅⋅⋅O intramolecular hydrogen bond

The single-crystal X-ray diffraction analysis of a β,γ-hybrid model peptide Boc-β-Ala-γ-Abu-NH2 revealed the existence of four crystallographically independent molecules (A, B, C and D conformers) in the asymmetric unit. The analysis revealed that unusual β-turn-like folded structures predominate, wherein the conformational space of non-proteinogenic β-Ala and γ-Abu residues are restricted to gauche-gauche-skew and skew-gauche-trans-skew orientations, respectively. Interestingly, the U-shaped conformers are seemingly stabilised by an effective unconventional C-H⋅⋅⋅O intramolecular hydrogen bond, encompassing a non-covalent 14-membered ring-motif. Taking into account the signs of torsion angles, these conformers could be grouped into two distinct categories, A/B and C/D, establishing the incidence of non-superimposable stereogeometrical features across a non-chiral one-component peptide model system, that is, "mirror-image-like" relationships. The natural occurrence of β-Ala and γ-Abu entities in various pharmacologically important molecules, coupled with their biocompatibilities, highlight how the non-functionalised β,γ-hybrid segment may offer unique advantages for introducing and/or manipulating a wide spectrum of biologically relevant hydrogen bonded secondary structural mimics in short synthetic peptides.

Tetrad selectivity in polarity-driven switch peptides: the best turn is not always the best nucleation site

In some naturally occurring protein sequences, an abrupt, concerted refolding from β-sheet to helical conformation occurs when the polarity of the surrounding medium drops below a critical level. This switch-like behaviour was first observed on the HIV-1 envelope glycoprotein gp120, where it plays a crucial role in the efficient binding of gp120 to the T-cell receptor CD4. Previous work had shown that an N-terminal amino acid tetrad LPCR and a Trp located 5-20 residues downstream to the tetrad are common motifs in polarity-driven switch peptides. The LPCR tetrad governs the folding of the subsequent residues and acts as a helix initiation site, whereas the Trp is responsible for the cooperative character of the structural change due to multiple, simultaneous interactions of its quadrupole moment with several amino acid residues within the sequences. Here we identify and characterize new families of switch peptides that use different, turn-probable tetrads (LPST and VPSR) as helix initiation sites at the N-terminus. We have also been able to demonstrate that some tetrads with extremely high turn probability do not serve as helix initiation sites. Comparison of these with LPCR and the newly discovered tetrads LPST and VPSR has allowed a more comprehensive description of the physico-chemical properties of helix-inducing tetrads. The deeper understanding of the intrinsic properties of switch sequences allows the design of artificial polarity-driven switches, applicable in engineering of, e.g. controllable binding sites in artificial proteins.

Solid state and solution conformations of a hybrid alphagammaalphaalphagammaalpha hexapeptide. Characterization of a backbone expanded analog of the alpha-polypeptide 3(10)-helix

The stereochemically constrained gamma amino acid residue gabapentin (1-(aminomethyl)cyclohexaneacetic acid, Gpn) has been incorporated into a host alpha-peptide sequence. The structure of a hybrid alphagammaalphaalphagammaalpha peptide, Boc-Leu-Gpn-Aib-Leu-Gpn-Aib-OMe in crystals reveals a continuous helical conformation stabilized by three intramolecular 4 --> 1 C(12) hydrogen bonds across the alphagamma/alphagamma segments and one C(10) hydrogen bond across the central alphaalpha segment. This conformation corresponds to an expanded analog of the canonical all-alpha polypeptide 3(10)-helix, with insertion of two additional backbone atoms at each gamma residue. Solvent dependence of NH chemical shifts in CDCl(3) solution are consistent with conformation in which the NH groups of Aib (3), Leu (4), Gpn (5), and Aib (6) are hydrogen bonded, a feature observed in the solid state. The nonsequential NOEs between Gpn (2) NH <--> Leu (4) NH and Gpn (2) NH <--> Gpn (5) NH support the presence of additional conformations in solution. Temperature-dependent line broadening of NH resonances confirms the occurrence of rapid exchange between multiple conformations at room temperature. Two conformational models which rationalize the observed nonsequential NOEs are presented, both of which contain three hydrogen bonds and are consistent with the known stereochemical preferences of the Gpn residue.

Testing β-helix terminal coils stability by targeted substitutions with non-proteogenic amino acids: A molecular dynamics study

The search for new building block templates useful for nanostructures design, targets protein motifs with a wide range of structures. Stabilizing these building blocks when extracted from their natural environment becomes a fundamental goal in order to successfully control their assembly. Targeted replacements of natural residues by conformationally constrained amino acids were shown to be a successful strategy to achieve such stabilization. In this work, the effect of replacing natural amino acids by non-proteogenic residues in a beta-helix building block has been evaluated using extensive molecular dynamics simulations. Here, we focus on systematic substitutions of valine residues present in beta-sheet segments of a beta-helical building block excised from Escherichia coli galactoside acetyltransferase, residues 131-165. Four different types of non-proteogenic amino acids have been considered for substitution: (i) one dehydroamino acid, (ii) two d-amino acids, (iii) one beta-amino acid and (iv) two alpha,alpha-dialkylamino acids. Our results indicate that the ability of non-proteogenic amino acids to stabilize small building block motifs is site-dependent. We conclude that if the replacement does not alter the energy balance between attractive non-covalent interactions and steric hindrance, synthetic residues are suitable candidates to nucleate beta-helix formation.

Hybrid Peptides: Expanding the β Turn in Peptide Hairpins by the Insertion of β-, γ-, and δ-Residues

The beta turn segment in designed peptide hairpins has been expanded by the insertion of beta-, gamma- and delta-amino acids at the i+2 position. The model octapeptides Boc-Leu-Phe-Val-DPro-Ac6c-Leu-Phe-Val-OMe (1), Boc-Leu-Phe-Val-DPro-beta3-Ac6c-Leu-Phe-Val-OMe (2), and Boc-Leu-Phe-Val-DPro-Gpn-Leu-Phe-Val-OMe (3) have been shown to adopt beta hairpin conformations in methanol by the observation of key diagnostic nuclear Overhauser effects. Boc-Leu-Val-Val-DPro-delta-Ava-Leu-Val-Val-OMe (4) adopts a beta hairpin conformation in crystals; this is stabilized by three cross-strand hydrogen bonds as demonstrated by X-ray diffraction. The canonical C10 turn in an alpha-alpha segment is expanded to C11, C12, and C13 turns in alpha-beta, alpha-gamma, and alpha-delta segments, respectively. The crystal structures of Piv-LPro-beta3-Ac6c-NHMe (5) and Boc-Ac6c-Gpn-Ac6c-OMe (6) reveal intramolecularly hydrogen-bonded C11 and C12 conformations, respectively. Computer modeling of octapeptide sequences that contain centrally positioned hybrid-turn segments, by using turn parameters derived from the structures of peptides 5 and 6, establishes the stereochemical acceptability of the beta hairpins in the cases of peptides 2 and 3. Accommodation of omega-amino acids into the turn segments is achieved by the adoption of gauche conformations around the backbone C--C bonds.

Tuning the beta-turn segment in designed peptide beta-hairpins: construction of a stable type I' beta-turn nucleus and hairpin-helix transition promoting segments

Designed octapeptides Boc-Leu-Val-Val-Aib-(D)Xxx-Leu-Val-Val-OMe ((D)Xxx = (D)Ala, 3a;(D)Val, 3c and (D)Pro, 5a) and Boc-Leu-Phe-Val-Aib-(D)Ala-Leu-Phe-Val-OMe (3b) have been investigated to construct models of a stable type I' beta-turn nucleated hairpin and to generate systems for investigating helix-hairpin conformational transitions. Peptide 5a, which contains a central Aib-(D)Pro segment, is shown to adopt a stable type I' beta-turn nucleated hairpin structure, stabilized by four cross-strand hydrogen bonds. The stability of the structure in diverse solvents is established by the observation of all diagnostic NOEs expected in a beta-hairpin conformation. Replacement of (D)Pro5 by (D)Ala/(D)Val (3a-c) results in sequences that form beta-hairpins in hydrogen bonding solvents like CD(3)OH and DMSO-d(6). However, in CDCl(3) evidence for population of helical conformations is obtained. Peptide 6b (Boc-Leu-Phe-Val-Aib-Aib-Leu-Phe-Val-OMe), which contains a centrally positioned Aib-Aib segment, provides a clear example of a system, which exhibits a helical conformation in CDCl(3) and a significant population of both helices and hairpins in CD(3)OH and DMSO-d(6). The coexistence of multiple conformations is established by the simultaneous observation of diagnostic NOEs. Control over stereochemistry of the central beta-turn permits generation of models for robust beta-hairpins and also for the construction of systems that may be used to probe helix-hairpin conformational transitions.

Structural studies of model peptides containing β-, γ- and δ-amino acids

The crystal structures of five model peptides Piv-Pro-Gly-NHMe (1), Piv-Pro-betaGly-NHMe (2), Piv-Pro-betaGly-OMe (3), Piv-Pro-deltaAva-OMe (4) and Boc-Pro-gammaAbu-OH (5) are described (Piv: pivaloyl; NHMe: N-methylamide; betaGly: beta-glycine; OMe: O-methyl ester; deltaAva: delta-aminovaleric acid; gammaAbu: gamma-aminobutyric acid). A comparison of the structures of peptides 1 and 2 illustrates the dramatic consequences upon backbone homologation in short sequences. 1 adopts a type II beta-turn conformation in the solid state, while in 2, the molecule adopts an open conformation with the beta-residue being fully extended. Piv-Pro-betaGly-OMe (3), which differs from 2 by replacement of the C-terminal NH group by an O-atom, adopts an almost identical molecular conformation and packing arrangement in the solid state. In peptide 4, the observed conformation resembles that determined for 2 and 3, with the deltaAva residue being fully extended. In peptide 5, the molecule undergoes a chain reversal, revealing a beta-turn mimetic structure stabilized by a C-H...O hydrogen bond.