Nanofiber formation of amphiphilic cyclic tri‐β‐peptide

A novel amphiphilic cyclic peptide composed of two β‐glucosamino acids and one trans‐2‐aminocyclohexylcarboxylic acid was synthesized and investigated on assembly formation. The cyclic tri‐β‐peptide was self‐assembled into rodlike crystals or nanofibers depending on preparative conditions. The rodlike crystals showed a layer spacing of 4.8 Å along the long axis, and columnar spacings of 10.8 and 21.5 Å by electron diffraction analysis along the short axis. The former confirms the columnar structure upon molecular stacking, and the latter indicates triple bundle formation of the columnar assemblies. Fourier transform infrared (FT‐IR) measurement of the fibrous assembly showed formation of homogeneous hydrogen bonds among amide groups, also supporting the molecular stacking of cyclic β‐peptides. Straight nanofibers with uniform diameter were also uniquely obtained. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Double assembly composed of lectin association with columnar molecular assembly of cyclic tri-beta-peptide having sugar units

A novel double assembly was prepared by association between a columnar molecular assembly of cyclic tri-beta-peptides having sugar units and lectins. The NMR, FT-IR, and circular dichroism (CD) spectroscopy as well as computational calculations revealed that this compound took a flat and C3 symmetrical conformation and that the amide N-H and C=O groups protruded vertically to the ring plane. This disk-shaped molecule stacked one by one to form a columnar structure via intermolecular hydrogen bonds between the amide groups. WGA lectin moderately bound to this columnar assembly to form a double assembly. Another lectin (Con A) disturbed the columnar structure upon strong binding, and RCA lectin showed no binding. Fluorescence spectroscopy revealed that the association between WGA lectin and columnar assembly of cyclic glycopeptide could be achieved due to the high density of the hydroxyl groups on the assembly surface (cluster effects). Interestingly, after cross-linking the lectins bound to the columnar assembly (the double assembly) by glutaraldehyde, the core column of cyclic tri-beta-peptides could be washed away to leave the protein nanotube.     

Molecular assembly formation of cyclic hexa-beta-peptide composed of acetylated glycosamino acids

A novel cyclic hexamer of acetylated beta-glycosamino acid was synthesized and its conformation and molecular assembly formation was investigated. Variable temperature NMR study indicated that the cyclic hexapeptide took a C(3) symmetric conformation at room temperature, but at elevated temperatures a C(6) symmetric one, which was not due to averaging of the C(3) symmetric conformation, appeared. Computational geometry optimization showed that the C(6) symmetric conformation was a highly planar structure with amide groups orienting perpendicular to the ring plane. The cyclic hexa-beta-peptide formed rod-shaped crystals from an N,N-dimethyl formamide solution at elevated temperature. The optical microscopy observation with a sensitive tint plate under cross-nicol configuration and electron diffraction analysis of the crystals revealed that the cyclic hexa-beta-peptides were stacked one after the other to form a regular nanotube structure.     

A theoretical study on the stability of CNT encased cyclic peptide beyond hydrogen bond cut-off

The Carbon nanotubes (CNT) are potential candidate for many biomedical applications especially in targeted drug delivery for cancer diseases. However, the use of CNT has limitations due to its insolubility in aqueous media. The self-assembly of cyclic peptide encased on the CNT has enhanced its dispersion in aqueous medium which extend their applications as antibacterial and drug delivery agents. To understand this process, an attempt has been made to investigate the dynamics and stability of trimer cyclic peptide encasing with CNT using classical molecular dynamics. The model cyclic peptide monomer constitutes 14 series of amino acids viz.; (cyclo-[(D-ARG-L-VAL-D-ARG-L-THR-D-AGR-L-LYS-D-GLY-L-ARG-D-ARG-L-ILE-D-ARG-L-ILE-D-PRO-L-PRO)]). Each cyclic peptide in the assembly stacking far apart at approximately 15 Å each other beyond hydrogen bond cut-off distance. The trimer was observed to be stable only over 10 ns of entire MD trajectory. But when there is electrostatic interaction between cyclic peptides at 6.5 Å distance then assembly is stable for entire 50 ns. Our result reveals that for a stable assembly, beyond the hydrogen bond cut-off distance, the electrostatic interaction plays significant role.     

Molecular structure of cyclic deoxydiadenylic acid at atomic resolution

The molecular structure of a small cyclic nucleotide, cyclic deoxydiadenylic acid, has been determined by single-crystal X-ray diffraction analysis and refined to an R factor of 7.8% at 1.0-A resolution. The crystals are in the monoclinic space group C2 with unit cell dimensions of a = 24.511 (3) A, b = 24.785 (3) A, c = 13.743 (3) A, and beta = 94.02 (2) degrees. The structure was solved by the direct methods program SHELXS-86. There are 2 independent cyclic d(ApAp) molecules, 2 hydrated magnesium ions, and 26 water molecules in the asymmetric unit of the unit cell. The two cyclic d(ApAp) molecules have similar conformations within their 12-membered sugar-phosphate backbone ring, but they have quite different appearances due to the different glycosyl torsion angles that make one molecule more compact and the other extended and open. Three of the four deoxyribose rings are in the less common C3'-endo conformation. All four phosphate groups have their phosphodiester torsion angles alpha/zeta in the gauche(+)/gauche(+) conformation. One of the cyclic d(ApAp) molecules associates with another symmetry-related molecule to form a self-intercalated dimer that is a stable structure in solution, as observed in NMR studies. Many interesting intermolecular interactions, including base-base stacking, ribose-base stacking, base pairing, base-phosphate hydrogen bonding, and metal ion-phosphate interactions, are found in the crystal lattice. This structure may be relevant for understanding the conformational potentiality of an endogenous biological regulator of cellulose synthesis, cyclic (GpGp).     

Folding and aggregation kinetics of a beta-hairpin

We have investigated the solution structure, equilibrium properties, and folding kinetics of a 17-residue beta-hairpin-forming peptide derived from the protein ubiquitin. NMR experiments show that at 4 degrees C the peptide has a highly populated beta-hairpin conformation. At protein concentrations higher than 0.35 mM, the peptide aggregates. Sedimentation equilibrium measurements show that the aggregate is a trimer, while NMR indicates that the beta-hairpin conformation is maintained in the trimer. The relaxation kinetics in nanosecond laser temperature-jump experiments reveal a concentration-independent microsecond phase, corresponding to beta-hairpin unfolding-refolding, and a concentration-dependent millisecond phase due to oligomerization. Kinetic modeling of the relaxation rates and amplitudes yields the folding and unfolding rates for the monomeric beta-hairpin, as well as assembly and disassembly rates for trimer formation consistent with the equilibrium constant determined by sedimentation equilibrium. When the net charge on the peptides and ionic strength were taken into account, the rate of trimer assembly approaches the Debye-Smoluchowski diffusion limit. At 300 K, the rate of formation of the monomeric hairpin is (17 micros)(-1), compared to rates of (0.8 micros)(-1) to (52 micros)(-1) found for other peptides. After using Kramers theory to correct for the temperature dependence of the pre-exponential factor, the activation energy for hairpin formation is near zero, indicating that the barrier to folding is purely entropic. Comparisons with previously measured rates for a series of hairpins are made to distinguish between zipper and hydrophobic collapse mechanisms. Overall, the experimental data are most consistent with the zipper mechanism in which structure formation is initiated at the turn, the mechanism predicted by the Ising-like statistical mechanical model that was developed to explain the equilibrium and kinetic data for the beta-hairpin from protein GB1. In contrast, the majority of simulation studies favor a hydrophobic collapse mechanism. However, with few exceptions, there is little or no quantitative comparison of the simulation results with experimental data.     

Structure and stability of DNA containing an aristolactam II-dA lesion: implications for the NER recognition of bulky adducts

Aristolochic acids I and II are prevalent plant toxicants found in the Aristolochiaceae plant family. Metabolic activation of the aristolochic acids leads to the formation of a cyclic N-hydroxylactam product that can react with the peripheral amino group of purine bases generating bulky DNA adducts. These lesions are mutagenic and established human carcinogens. Interestingly, although AL-dG adducts progressively disappear from the DNA of laboratory animals, AL-dA lesions has lasting persistence in the genome. We describe here NMR structural studies of an undecameric duplex damaged at its center by the presence of an ALII-dA adduct. Our data establish a locally perturbed double helical structure that accommodates the bulky adduct by displacing the counter residue into the major groove and stacking the ALII moiety between flanking bases. The presence of the ALII-dA perturbs the conformation of the 5'-side flanking base pair, but all other pairs of the duplex adopt standard conformations. Thermodynamic studies reveal that the lesion slightly decreases the energy of duplex formation in a sequence-dependent manner. We discuss our results in terms of its implications for the repair of ALII-dA adducts in mammalian cells.     

Conformational analysis of oligoarabinonucleotides. An NMR and CD study.

A 500 and 300 MHz proton NMR study of the series of oligoarabinonucleotides 5'aAMP, 3'aAMP, aA-aA, (aA-)2aA and (aA-)3aA is presented. In addition, circular dichroism is used to study the stacking behaviour of aA-aA. The complete 1H-NMR spectral assignment of the compounds (except the tetramer) is given. Proton-proton and proton-phosphorus coupling constants, obtained by computer simulation of the high-field region of the spectra, yield information on the conformation of the arabinose rings (N- or S-type) and on the intramolecular stacking properties of the dimer and the trimer. The monomers 5'aAMP and 3'aAMP exhibit a preference for N- and S-type sugar conformation, respectively. It is shown that the dimer aA-aA at low temperature prefers a mixed stacked state of the type aA(S)-aA(N). In the trimer the aA(2)-aA(3) fragment exhibits a conformation similar to that found in the dimer, whereas the aA(1) residue prefers to adopt S-type sugar and has some tendency to stack upon residue aA(2).     

Stereospecific complexation of uranyl ion with tartaric acids studied by NMR spectroscopy

A full pH range ¹H and ¹³C NMR study was performed on the complexation of UO₂²⁺ with (D,L)- and meso-tartaric acids, for variable concentrations and molar ratios, in comparison with (D)-tartaric acid. The main result is that, in spite of the already high number of complexes formed with the active ligand, an additional species occurs with the racemic mixture for which experimental evidence indicates a cyclic trimer structure. A smaller number of complexes is formed with meso-tartaric acid. Information on the conformation of bound ligand is also obtained.     

NCα-gem-dimethylated peptoid side chains: A novel approach for structural control and peptide sequence mimetics

The design of linear peptoid oligomers adopting well-defined secondary structures while mimicking defined peptide primary sequences is a major challenge in the context of drug discovery. To this end, chemists have developed cis-inducing peptoid side chains to build robust polyproline type I helices. However, the number of efficient examples remains scarce and chemical diversity accessible through the use of these side chains is limited. Herein, we introduce an array of NCα-gem-dimethylated peptoid residues mimicking proteinogenic amino acids. Submonomer synthesis and block-coupling approaches were explored to access heterooligomers incorporating these novel types of side chains. NMR studies of monomer and trimer models showed that the NCα-gem-dimethylated groups exert complete cis control on the backbone amide conformation. Lastly, a preliminary molecular modeling study gave an insight into the preferred orientation of the substituents of the NCα-gem-dimethyl side chains relative to the peptoid backbone.     

Template-assembled triple-helical peptide molecules: mimicry of collagen by molecular architecture and integrin-specific cell adhesion

Most proteins fold into specific structures to exert their biological functions, and therefore the creation of protein-like molecular architecture is a fundamental prerequisite toward realizing a novel biologically active protein-like biomaterial. To do this with an artificial collagen, we have engineered a peptide template characterized by its collagen-like primary structure composed of Gly-Phe-Gly-Glu-Glu-Gly sequence to assemble (Pro-Hyp-Gly)n (n = 3 and 5) into triple-helical conformations that resemble the native structure of collagen. The peptide template has three carboxyl groups connected to the N-termini of three collagen peptides. The coupling was accomplished by a simple and direct branching protocol without complex strategies. A series of biophysical studies, including melting curve analyses and CD and NMR spectroscopy, demonstrated the presence of stable triple-helical conformation in the template-assembled (Pro-Hyp-Gly)3 and (Pro-Hyp-Gly)5 solution. Conversely, nontemplated peptides showed no evidence of assembly of triple-helical structure. A cell binding sequence (Gly-Phe-Hyp-Gly-Glu-Arg) derived from the collagen alpha1(I) chain was incorporated to mimic the integrin-specific cell adhesion of collagen. Cell adhesion and inhibition assays and immunofluorescence staining revealed a correlation of triple-helical conformation with cellular recognition of collagen mimetics in an integrin-specific way. This study offers a robust strategy for engineering native-like peptide-based biomaterials, fully composed of only amino acids, by maintaining protein conformation integrity and biological activity.     

Carbon nanotube prevents the secondary structure formation of amyloid-β trimers: an all-atom molecular dynamics study

Abstract

Increasing evidence shows that the formation of misfolded aggregates amyloid-β (Aβ) peptide is associated with the Alzheimer’s disease (AD). Recent experiments reveal a significant correlation of the amount of trimer species bound to neurons with increasing neuro-toxicity. Our previous computational study demonstrated that carbon nanotubes (CNT) can inhibit effectively the formation of β-sheet-rich oligomers of Aβ(16-22) – a hydrophobic peptide essential for Aβ fibrillization. However, the influence of CNT on the oligomers formed by full-length Aβ remains elusive. In this study, we have investigated the conformational dynamics of Aβ(1-42) trimer, built from an NMR structure of α-helical monomer, in the absence and presence of a single-walled carbon nanotube (SWCNT). Our simulations demonstrate that SWCNT can significantly hinder the trimerisation and prevents the secondary structure formation of Aβ(1-42) peptide. Hydrophobic and aromatic stacking interactions between SWCNT and Aβ play important roles in the secondary structure formation of the Aβ trimer. This study reveals a complete picture of the detailed preventable mechanism of full-length Aβ(1-42) by SWCNT, providing theoretical insights into the development of drug candidates of AD.     

Binding affinity difference induced by the stereochemistry of the sulfoxide bridge of the cyclic peptide inhibitors of Grb2-SH2 domain: NMR studies for the structural origin

The SAR study on a phage library-derived non-phosphorylated cyclic peptide ligand of Grb2-SH2 domain indicates that the configuration of the cyclization linkage is crucial for assuming the active binding conformation. When the thioether linkage was oxidized to the two chiral sulfoxides, the R-configured sulfoxide-cyclized peptide displayed 10-30 times more potency than the corresponding S-configured one in binding affinity to the Grb2-SH2 domain. In this paper, the solution structures of such a pair of sulfoxide-bridged cyclic peptide diastereoisomers, i.e., cyclo[CH(2)CO-Gla(1)-L-Y-E-N-V-G-NPG-Y-(R/S)C(O)(10)]-amide, were determined by NMR and molecular dynamics simulation. Results indicate that the consensus sequence of Y(3)-E(4)-N(5)-V(6) in both diastereoisomers adopt a beta-turn conformation; however, the R-configured peptide forms an extended structure with a circular backbone conformation, while the S-configured isomer forms a compact structure with key residues buried inside the molecule. The average root-mean-square deviations were found to be 0.756 and 0.804 A, respectively. It is apparent that the chiral S-->O group played a key role in the solution structures of the sulfoxide-bridged cyclic peptides. The R-sulfoxide group forms an intramolecular hydrogen bond with the C-terminal amide, conferring a more rigid conformation with all residues protruding outside except for Leu2, in which the Gla1 and Tyr3 share an overlapping function as previous SAR studies proposed. Additionally, the extended structure endows a more hydrophilic binding surface of the R-configured peptide to facilitate its capture by its targeted protein. In comparison, the S-configured sulfoxide was embedded inside the ligand peptide leading to a compact structure, in which the essential residues of Gla1, Tyr3, and Asn5 form multiple intramolecular hydrogen bonds resulting in an unfavorable conformational change and a substantial loss of the interaction with the protein. The solution structures disclosed by our NMR and molecular dynamics simulation studies provide a molecular basis for understanding how the chirality of the cyclization linkage remarkably discriminates in terms of the binding affinity, thus advancing the rational design of potent non-phosphorylated inhibitors of Grb2-SH2 domain as antitumor agents.     

Structural modeling of the distamycin A-d(CGCGAATTCGCG)2 complex using 2D NMR and molecular mechanics

The structure of the distamycin A-d(CGCGAATTCGCG)2 complex has been determined through a combination of SKEWSKY and NOESY 2D NMR experiments and molecular mechanics calculations. NMR data provided upper bounds on many proton-proton pairs. The advantage of the SKEWSKY/NOESY method is that small groups of strongly coupled spins can be treated accurately as isolated systems. The AMBER molecular mechanics package, modified to include the NMR constraints, was used in energy refinements. Distamycin A fits snugly into the 5'-AATT-3' minor-groove binding site. Structural analysis revealed van der Waals contacts between A5, A6, and A18 C2H and drug H3 protons, potential three-center hydrogen bonding between drug amide protons and adenine N3 and thymine O2 atoms analogous to the spine of hydration in the crystal structure of the free DNA, and stacking of the sugar O1' atoms of A6-C21, T7-T20, and, T8-T19, over drug pyrrole rings 1, 2, and 3, respectively. In addition to hydrophobic effects, hydrogen bonding, and electrostatic interactions proposed by others, it is suggested that stacking interactions between DNA sugar O1' atoms and the three drug pyrrole rings contribute to the stability of the complex.     

Trimeric structure of PRL-1 phosphatase reveals an active enzyme conformation and regulation mechanisms

The PRL phosphatases, which constitute a subfamily of the protein tyrosine phosphatases (PTPs), are implicated in oncogenic and metastatic processes. Here, we report the crystal structure of human PRL-1 determined at 2.7A resolution. The crystal structure reveals the shallow active-site pocket with highly hydrophobic character. A structural comparison with the previously determined NMR structure of PRL-3 exhibits significant differences in the active-site region. In the PRL-1 structure, a sulfate ion is bound to the active-site, providing stabilizing interactions to maintain the canonically found active conformation of PTPs, whereas the NMR structure exhibits an open conformation of the active-site. We also found that PRL-1 forms a trimer in the crystal and the trimer exists in the membrane fraction of cells, suggesting the possible biological regulation of PRL-1 activity by oligomerization. The detailed structural information on the active enzyme conformation and regulation of PRL-1 provides the structural basis for the development of potential inhibitors of PRL enzymes.     

Global structure of a DNA three-way junction by solution NMR: towards prediction of 3H fold

Three-way junctions (3H) are the simplest and most commonly occurring branched nucleic acids. They consist of three double helical arms (A to C), connected at the junction point, with or without a number of unpaired bases in one or more of the three different strands. Three-way junctions with two unpaired bases in one strand (3HS2) have a high tendency to adopt either of two alternative stacked conformations in which two of the three arms A, B and C are coaxially stacked, i.e. A/B-stacked or A/C-stacked. Empirical stacking rules, which successfully predict for DNA 3HS2 A/B-stacking preference from sequence, have been extended to A/C-stacked conformations. Three novel DNA 3HS2 sequences were designed to test the validity of these extended stacking rules and their conformational behavior was studied by solution NMR. All three show the predicted A/C-stacking preference even in the absence of multivalent cations. The stacking preference for both classes of DNA 3HS2 can thus be predicted from sequence. The high-resolution NMR solution structure for one of the stacked 3HS2 is also reported. It shows a well-defined local and global structure defined by an extensive set of classical NMR restraints and residual dipolar couplings. Analysis of its global conformation and that of other representatives of the 3H family, shows that the relative orientations of the stacked and non-stacked arms, are restricted to narrow regions of conformational space, which can be understood from geometric considerations. Together, these findings open up the possibility of full prediction of 3HS2 conformation (stacking and global fold) directly from sequence.     

Conformational characteristics of the trinucleoside diphosphate xyloA2'-5'xyloA2'-5'xyloA. A nuclear magnetic resonance and CD study.

In this paper the conformational analysis of the 2'-5' linked xylotrinucleotide xA2'-5'xA2'-5'xA is reported. The title compound is an analogue of A2'-5'A2'-5'A, which compound was shown to display inhibitive effects on protein synthesis. The complete 1H-NMR assignment of the high field spectral region of the xylose trimer is given. Modes of base-base stacking are extracted from coupling constant data at various temperatures. Circular dichroic (CD) spectra confirm the presence of stacked states at low temperature. Xylonucleosides are known to prefer the N-type sugar conformation. However, in the present trimer the S-type conformer is suggested to partake in stacked conformations. Two types of stacking in the two constituent dimer fragments of the trimer are proposed to rationalize the NMR data: xA(1)N-xA(2)S and xA(2)N-xA(3)S.     

Application of Raman spectroscopy to biological macromolecules.

The Raman spectra of biological macromolecules arise from molecular vibrations of either the backbone chains or the side chains. The frequencies of the Raman bands lie in a region between 200 cm-1 and 3000 cm-1. From certain frequencies of the vibrations of the backbone chains one can determine the conformation or secondary structure of a macromolecule. Thus for polypeptides and proteins the frequencies of the Amide I and Amide III vibrations allow one to determine the averge conformation of their backbone chain. In polynucleotides and nucleic acids, the frequency of the phosphate diester stretch of the phosphate furanose chain varies between 814 cm-1 for A conformation and 790 cm-1 for B conformation. Raman spectra of the bases in nucleic acids can be used to determine base stacking and hydrogen bonding interactions. Thus Raman spectroscopy is an important tool for determining the conformation structure of proteins and nucleic acids.     

Stabilization of RNA stacking by pseudouridine.

The effect of the modified nucleoside pseudouridine (psi) on RNA structure was compared with uridine. The extent of base stacking in model RNA oligonucleotides was measured by 1H NMR, UV, and CD spectroscopy. The UV and CD results indicate that the model single-stranded oligoribonucleotides AAUA and AA psi A form stacked structures in solution and the CD results for AA psi A are consistent with a general A-form helical conformation. The AA psi A oligomer exhibits a greater degree of UV hypochromicity over the temperature range 5-55 degrees C, consistent with a better stacked, more A-form structure compared with AAUA. The extent of stacking for each nucleotide residue was inferred from the percent 3'-endo sugar conformation as indicated by the H1'-H2' NMR scalar coupling. This indirect indication of stacking was confirmed by sequential NOE experiments. NMR measurements as a function of temperature indicate that pseudouridine forms a more stable base stacking arrangement than uridine, an effect that is propagated throughout the helix to stabilize stacking of neighboring purine nucleosides. The N1-H imino proton in AA psi A exchanges slowly with solvent, suggesting a role for the extra imino proton in stabilizing the conformation of pseudouridine. These results show that the conformational stabilization is an intrinsic property of pseudouridine occurring at the nucleotide level. The characteristics of pseudouridine in these models are consistent with earlier studies on intact rRNA, indicating that pseudouridine probably performs the same stabilizing function in most structural contexts.