Conformational investigations on glycosylated asparagine-oligopeptides of increasing chain length.

Stepwise solution syntheses of the homo-oligomers Boc-(Asn)n-NHCH3 (n = 1-5; I1-5), Boc-[[GlcNAc(Ac)3beta]Asn]n-NHCH3 (n = 1-8; II1-8), and Boc-[(GlcNAcbeta)Asn]n-NHCH3 (n = 1-8; III1-8) are described. Members of the series III were obtained by deacetylation of the corresponding members of the series II. The conformational preferences of the N-protected homo-peptides of the three series were investigated by spectroscopic techniques. 1H-NMR measurements were carried out in various solvents; the CD spectra were recorded in water, aqueous SDS and TFE. The poor solubility of the oligomers of the three series prevented FT-IR measurements in solution. NMR and IR measurements indicate the existence of unordered structures containing some gamma-turns in the carbohydrate-free oligomers and the presence of beta-turns in the glycosylated oligopeptides, whether acetylated or not. The CD spectra do not indicate the presence of organized structures. The sugar moieties apparently do not have a structure-inducing effect on the asparagine homo-oligomer main chain.     

Conformation and calcium binding properties of gastrin fragments of increasing chain length

Conformation and calcium binding properties of a series of gastrin-related peptides, in which the glutamic acid sequence at the N-terminal portion of the molecule has been elongated step by step, have been investigated using circular dichroism spectroscopy. A working hypothesis about the structure of these hormones in trifluoroethanol has been proposed. The structure comprises aβ-bend located at the level of the sequence Ala-Tyr-Gly-Trp. A correlation between chain elongation and increase of biological potency has been observed. All examined peptides strongly interact with calcium ions in trifluoroethanol. The variation of the circular dichroism spectra upon calcium addition provided some information about the groups involved in the coordination of the ions. Our results allow the hypothesis of the presence of one binding site, located at the C-terminal portion of the molecule in the gastrin octapeptide, and of an additional site at the N-terminus, in the longer fragments. The carboxyl function of Asp and Glu side-chains, at the two ends of the molecules, are probably involved in the interaction with the metal ions.     

Polypeptide models of elastin: CD and NMR studies on synthetic poly(X-Gly-Gly).

Poly(X-Gly-Gly), simple structural models for the hydrophobic, proline-devoid, regions of elastin, have been synthesized and studied by circular dichroism and NMR spectroscopies. The results gave evidence of type II beta-turns as the only ordered structure present in the polymers. The stability of the turns has been shown to decrease on hydration and to increase in the series Leu less than Ala less than Val less than Ile.     

Effect of the ΔPhe residue configuration on a didehydropeptides conformation: A combined CD and NMR study

Conformations of two pairs of dehydropeptides with the opposite configuration of the ΔPhe residue, Boc‐Gly‐Δ^ZPhe‐Gly‐Phe‐OMe ( Z‐ OMe ), Boc‐Gly‐Δ^EPhe‐Gly‐Phe‐OMe ( E‐ OMe ), Boc‐Gly‐Δ^ZPhe‐Gly‐Phe‐p‐NA ( Z‐p‐ NA ), and Boc‐Gly‐Δ^EPhe‐Gly‐Phe‐p‐NA ( E‐p‐ NA ) were compared on the basis of CD and NMR studies in MeOH, trifluoroethanol (TFE), MeCN, chloroform, and dimethylsulfoxide (DMSO). The CD results were used as the additional input data for the NMR‐based determination of the detailed solution conformations of the peptides. It was found that E‐ OMe is unordered and Z‐ OMe , Z‐p‐ NA , and E‐p‐ NA adopt the β‐turn conformation. There are two overlapping β‐turns in each of those peptides: type II and type III′ in Z‐ OMe and Z‐p‐ NA , and two type III in E‐p‐ NA . The ordered structure‐inducing properties of Δ^ZPhe and Δ^EPhe in the peptides studied depend on the C‐terminal blocking group. In methyl esters, the Δ^ZPhe residue is a strong inducer of ordered conformations whereas the Δ^EPhe one has no such properties. In p‐nitroanilides, both isomers of ΔPhe cause the peptides to adopt ordered structures to a similar extent. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 1055–1064, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Conformational properties of tripeptides having cyclic dipeptide backbone and their catalytic properties for enantiomer-selective hydrolysis

Conformation in aqueous solution at pH 6.95 of tripeptides having cyclic dipeptide backbones, cyclo[l-Glu(l-Leu-OBzl)-l-His] and cyclo[l-Glu(l-Leu-OH)-l-His], was investigated by u.v., c.d. and n.m.r. spectroscopy and by the lanthanide probe method. In the major conformation of cyclo[l-Glu(l-Leu-OBzl)-l-His], the cyclic dipeptide backbone takes a flagpole-boat conformation in which the sidechain of the l-His residue is nearly parallel with the backbone plane and the sidechain of the l-Glu residue protrudes outside the backbone plane. In the major conformation of cyclo[l-Glu(l-Leu-OH)-l-His], the cyclic dipeptide backbone takes a flagpole-boat conformation in which the sidechains of the l-His and l-Glu residues are accommodated in the same side of the backbone plane so that the imidazolyl sidechain of l-His residue is twisted slightly. Tripeptides were not found to change the conformation when metal salts or ammonium salts such as Cl^?H₃N^?(CH₂)₁₁ COOEt, Gly-OEt-HCl, dl-Val-OEt-HCl and l-Leu-OEt-HCl were added, but a significant conformation change occurred upon adding d-Leu-OEt·HCl. If the same situation holds with the addition of α-amino acid p-nitrophenyl ester hydrochlorides, the previously reported enantiomer-selective catalysis by the tripeptides which hydrolysed d-Leu-OPh(NO₂·HCl faster than l-Leu-OPh(NO₂)·HCl can be explained; that is, the tripeptides change the conformation only when d-Leu-OPh(NO₂)·HCl is bound and consequently the intramolecular reaction is facilitated. This phenomenon may be compared with that of ‘induced fit’ in enzyme catalysis.     

Spectroscopic studies on elastin-like synthetic polypeptides

Spectroscopic studies on synthetic polypeptides containing the unit X-G-G (X = V or L) are reported. The sequences, constituting either fragments or model of elastin, were shown to adopt type II β-turns together with an ensemble of unordered conformations. Furthermore, it was found that the stability of the β-turns was depending on the nature of the X residue, on the hydration of the chain and, in the case of the sequence G-V-G-G-L, was decreasing by increasing the length of the chain.     

Conformational stability of porcine serum transferrin.

The conformation of porcine serum ferric transferrin (Tf) and its stability against denaturation were studied by circular dichroism. Tf was estimated to have 19-24% alpha-helix and 50-55% beta-sheet based on the methods of Chang et al. (Chang, C.T., Wu, C.-S.C., & Yang, J.T., 1978, Anal. Biochem. 91, 13-31) and Provencher and Glöckner (Provencher, S.W. & Glöckner, J., 1981, Biochemistry 20, 33-37). Removal of the bound ferric ions (apo-Tf) did not alter the overall conformation, but there were subtle changes in local conformation based on its near-UV CD spectrum. The Tfs were stable between pH 3.5 and 11. Denaturation by guanidine hydrochloride (Gu-HCl) showed two transitions at 1.6 and 3.4 M denaturant. The process of denaturation by acid and base was reversible, whereas that by Gu-HCl was partially reversible. The irreversible thermal unfolding of Tfs began at temperatures above 60 degrees C and was not complete even at 80 degrees C. The bound irons (based on absorbance at 460 nm) were completely released at pH < 4 or in Gu-HCl solution above 1.7 M, when the protein began to unfold, but they remained intact in neutral solution even at 85 degrees C. The NH2- and COOH-terminal halves of the Tf molecule obtained by limited trypsin digestion had CD spectra similar to the spectrum of native Tf, and the COOH-terminal fragment had more stable secondary structure than the NH2-terminal fragment.     

An inducible helix–Gly–Gly–helix motif in the N-terminal domain of histone H1e: A CD and NMR study

Knowledge of the structural properties of linker histones is important to the understanding of their role in higher-order chromatin structure and gene regulation. Here we study the conformational properties of the peptide Ac-EKTPVKKKARKAAGGAKRKTSG-NH(2) (NE-1) by circular dichroism and (1)H-NMR. This peptide corresponds to the positively charged region of the N-terminal domain, adjacent to the globular domain, of mouse histone H1e (residues 15-36). This is the most abundant H1 subtype in many kinds of mammalian somatic cells. NE-1 is mainly unstructured in aqueous solution, but in the presence of the secondary-structure stabilizer trifluoroethanol (TFE) it acquires an alpha-helical structure. In 90% TFE solution the alpha-helical population is approximately 40%. In these conditions, NE-1 is structured in two alpha-helices that comprise almost all the peptide, namely, from Thr17 to Ala27 and from Gly29 to Thr34. Both helical regions are highly amphipathic, with the basic residues on one face of the helix and the apolar ones on the other. The two helical elements are separated by a Gly-Gly motif. Gly-Gly motifs at equivalent positions are found in many vertebrate H1 subtypes. Structure calculations show that the Gly-Gly motif behaves as a flexible linker between the helical regions. The wide range of relative orientations of the helical axes allowed by the Gly-Gly motif may facilitate the tracking of the phosphate backbone by the helical elements or the simultaneous binding of two nonconsecutive DNA segments in chromatin.     

A helix-turn motif in the C-terminal domain of histone H1

The structural study of peptides belonging to the terminal domains of histone H1 can be considered as a step toward the understanding of the function of H1 in chromatin. The conformational properties of the peptide Ac-EPKRSVAFKKTKKEVKKVATPKK (CH-1), which belongs to the C-terminal domain of histone H1(o) (residues 99-121) and is adjacent to the central globular domain of the protein, were examined by means of 1H-NMR and circular dichroism. In aqueous solution, CH-1 behaved as a mainly unstructured peptide, although turn-like conformations in rapid equilibrium with the unfolded state could be present. Addition of trifluoroethanol resulted in a substantial increase of the helical content. The helical limits, as indicated by (i,i + 3) nuclear Overhauser effect (NOE) cross correlations and significant up-field conformational shifts of the C(alpha) protons, span from Pro100 to Val116, with Glu99 and Ala117 as N- and C-caps. A structure calculation performed on the basis of distance constraints derived from NOE cross peaks in 90% trifluoroethanol confirmed the helical structure of this region. The helical region has a marked amphipathic character, due to the location of all positively charged residues on one face of the helix and all the hydrophobic residues on the opposite face. The peptide has a TPKK motif at the C-terminus, following the alpha-helical region. The observed NOE connectivities suggest that the TPKK sequence adopts a type (I) beta-turn conformation, a sigma-turn conformation or a combination of both, in fast equilibrium with unfolded states. Sequences of the kind (S/T)P(K/R)(K/R) have been proposed as DNA binding motifs. The CH-1 peptide, thus, combines a positively charged amphipathic helix and a turn as potential DNA-binding motifs.     

Conformational analysis of the nonapeptide leuprorelin using NMR and molecular modeling

The nonapeptide Leuprorelin, one of the LHRH agonists, was studied by means of 2D nuclear magnetic resonance spectroscopy and molecular modeling. NOESY spectra in aqueous/deuterated methanol solution (50%H₂O/CD₃OD) at low temperature (268 K) revealed short-range nOe connectivities (i, i+1), characteristic of flexibility of the molecule. The H^N–H^N sequential connectivities observed provide evidence that the sequence has the propensity to form a bend involving residues 5 and 6 and the N-terminal segment. The -proton chemical shifts compared to random coil and additional data from the amide proton temperature coefficients support this assumption. One long-range nOe cross peak between H₂ –H^NEth is indicative of proximity between C- and N-termini.     

Conformational analysis of the nonapeptide leuprorelin using NMR and molecular modeling

Summary The nonapeptide Leuprorelin, one of the LHRH agonists, was studied by means of 2D nuclear magnetic resonance spectroscopy and molecular modeling. NOESY spectra in aqueous/deuterated methanol solution (50% H₂O/CD₃OD) at low temperature (268 K) revealed short-range nOe connectivities (i, i+1), characteristic of flexibility of the molecule. The H ^N -H ^N sequential connectivities observed provide evidence that the sequence has the propensity to form a bend involving residues 5 and 6 and the N-terminal segment. The α-proton chemical shifts compared to random coil and additional data from the amide proton temperature coefficients support this assumption. One long-range nOe cross peak between H ₂ ^α -H ^NEth is indicative of proximity between C- and N-termini.     

A guest-host approach to oligodepsipeptide structure

In this paper we investigate the effect of main chain isosteric replacement of specific amino acid residues by α-hydroxy acids. As part of a long term program specifically protected heptaglutamates were prepared and their circular dichroism and nuclear magnetic resonance spectra in various solvents were examined. From these experiments conformational preferences were deduced. We have also prepared oligo-(γ-methyl-glutamates) replacing the amino acids at specific positions along the chain with S-lactic acid and have elucidated the effect of these main chain isosteric replacements on oligopeptide structure. Analogues of collagen also have been prepared with glycolic acid replacing specific glycine residues. We synthesized the model hexamers Ac-Ala-Gly-Pro-Ala-Gly-Pro-NHMe, Ac-Ala-Glc-Pro-Ala-Gly-Pro-NHMe, and Ac-Ala-Gly-Pro-Ala-Glc-Pro-NHMe in order to study their structural characteristics under various conditions. Preliminary nuclear magnetic resonance and circular dichroism results are presented.     

Secondary structural analysis of the carboxyl‐terminal domain from different connexin isoforms

The connexin carboxyl‐terminal (CxCT) domain plays a role in the trafficking, localization, and turnover of gap junction channels, as well as the level of gap junction intercellular communication via numerous post‐translational modifications and protein–protein interactions. As a key player in the regulation of gap junctions, the CT presents itself as a target for manipulation intended to modify function. Specific to intrinsically disordered proteins, identifying residues whose secondary structure can be manipulated will be critical toward unlocking the therapeutic potential of the CxCT domain. To accomplish this goal, we used biophysical methods to characterize CxCT domains attached to their fourth transmembrane domain (TM4). Circular dichroism and nuclear magnetic resonance were complementary in demonstrating the connexin isoforms that form the greatest amount of α‐helical structure in their CT domain (Cx45 > Cx43 > Cx32 > Cx50 > Cx37 ≈ Cx40 ≈ Cx26). Studies compared the influence of 2,2,2‐trifluoroethanol, pH, phosphorylation, and mutations (Cx32, X‐linked Charcot‐Marie Tooth disease; Cx26, hearing loss) on the TM4‐CxCT structure. While pH modestly influences the CT structure, a major structural change was associated with phosphomimetic substitutions. Since most connexin CT domains are phosphorylated throughout their life cycle, studies of phospho‐TM4‐CxCT isoforms will be critical toward understanding the role that structure plays in regulating gap junction function. © 2015 Wiley Periodicals, Inc. Biopolymers 105: 143–162, 2016.     

Combined effect of the DeltaPhe or DeltaAla residue and the p-nitroanilide group on a didehydropeptides conformation

Two series of dehydropeptides of the general formulae Boc-Gly-X-Phe-p-NA, Boc-Gly-Gly-X-Phe-p-NA, Gly-X-Gly-Phe-p-NA.TFA, and Boc-Gly-X-Gly-Phe-p-NA, with X = Delta(Z)Phe and DeltaAla, were studied with NMR in DMSO and CDCl(3)-DMSO, and with CD in MeOH, MeCN, and TFE. The NMR spectra measured in DMSO suggest that peptides with the DeltaPhe residue next to Phe are folded whereas peptides with Gly between DeltaPhe and Phe are less ordered. NMR spectra of DeltaAla-containing peptides indicate that these peptides are flexible and their conformational equilibria are populated by many different conformations. The CD spectra show that conformational properties of the peptides studied are distinctly influenced by a mutual position of the dehydroamino acid residue and the p-NA group. They indicate that all dehydropeptides with the DeltaPhe residue, Boc-Gly-DeltaAla-Phe-p-NA, and Boc-Gly-Gly-DeltaAla-Phe-p-NA adopt ordered conformations in all solvents studied, presumably of the beta-turn type. The last two peptides exhibit surprising chiroptical properties. Their spectra show exciton coupling-like couplets in the region of the p-NA group absorption. This shape of CD spectra suggests a rigid, chiral conformation with a fixed disposition of the p-NA group. The CD spectra indicate that Boc-Gly-DeltaAla-Gly-Phe-p-NA and Gly-DeltaAla-Gly-Phe-p-NA.TFA are unordered, independently of the solvent.     

Conformational transition and liquid crystalline state of regenerated silk fibroin in water

The conformational transition of molecular chains of regenerated silk fibroin (SF) aqueous solution is systematically investigated by circular dichroism, Raman, IR, and UV-vis spectroscopies. It is found that an initial random coil conformation of the SF can be readily changed into an ordered beta-sheet structure by optimizing the solution conditions, such as the SF concentration, pH, temperature, or metal-ion content. Circular dichroic spectra quantitatively confirm a steadily decreased content of the random coil conformation but a significantly increased beta-sheet content after an ultrasonic or extruding treatment. Furthermore, the extrusion is more powerful to achieve high beta-sheet content than the ultrasonic. It is interesting that the polarized optical micrographs of the SF aqueous solution extruded by injection illustrate the formation and existence of liquid crystalline state. A study of extrusion in vitro could be used as a model system to understand the natural silk spinning process in silkworm.     

Ca2+-dependent conformational changes in bovine GCAP-2.

GCAP-2, a mammalian photoreceptor-specific protein, is a Ca2+-dependent regulator of the retinal membrane guanylyl cyclases (Ret-GCs). Sensing the fall in intracellular free Ca2+ after photo-excitation, GCAP-2 stimulates the activity of Ret-GC leading to cGMP production. Like other members of the recoverin superfamily, GCAP-2 is a small N-myristoylated protein containing four EF-hand consensus motifs. In this study, we demonstrate that like recoverin and neurocalcin, GCAP-2 alters its conformation in response to Ca2+-binding as measured by a Ca2+-dependent change in its far UV CD spectrum. Differences in the conformation of the Ca2+-bound and Ca2+-free forms of GCAP-2 were also observed by examining their relative susceptibility to V8 protease. In contrast to recoverin, we do not observe proteolytic cleavage of the myristoylated N-terminus of Ca2+-bound GCAP-2. NMR spectra also show that, in contrast to recoverin, the chemical environment of the N-terminus of GCAP-2 is not dramatically altered by Ca2+ binding. Despite the similarity of GCAP-2 and recoverin, the structural consequences of Ca2+-binding for these two proteins are significantly dissimilar.     

Crabrolin,a natural antimicrobial peptide: structural properties

A joint application of experimental and computational approaches has revealed the exceptionally high attitude of crabrolin, a 13‐residue peptide with sequence FLPLILRKIVTAL‐NH₂, to adopt alpha‐helix conformation not only in membrane‐mimicking solvents but also in the presence of a not negligible amount of water. Our study shows that this propensity essentially resides in the intrinsic thermodynamic stability of alpha‐helix conformation whose kinetic stability is drastically reduced in water solvent. Our analysis suggests that this is due to two effects enhanced by water: a more local effect consisting of the demolition of intra‐peptide H‐bonds, essential for the alpha‐helix formation, and a bulk – electrostatic – effect favoring conformational states more polar than alpha‐helix. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.