Conformational analysis of the type II and type III collagen alpha-1 chain C-telopeptides by 1H NMR and circular dichroism spectroscopy

The type II and type III collagen alpha-1 chain C-telopeptides are a 27 mer with the sequence NAc-GPGIDMSAFAGLGPREKGPDPLQYMRA and a 22mer,NAc-GGGVASLGAGEKGPVGYGYEYR, respectively. Their conformations have been studied in CD3OH/H2O (80/20) solution by means of two-dimensional proton NMR and CD spectroscopy. Based on TOCSY and NOESY experiments, all resonances were assigned and the conformational properties were analyzed in terms of vicinal NH-H alpha coupling constants, sequential and medium range NOEs and amide proton temperature coefficients. The conformation of the type II C-telopeptide is essentially extended. Evidence from CD spectroscopy suggests that a very minor proportion of the peptide might be helical (ca.8%), but the NMR data show no evidence for a non-linear structure. The observation of reduced amide proton temperature dependence coefficients in certain sections of the molecule can, in view of the absence of any other supporting evidence, only be interpreted in terms of local shielding from solvent for sterical reasons (large hydrophobic side-chains). The conformation of the type III C-telopeptide is mostly extended except for a beta-turn ranging from Gly8 to Glu11, which is stabilized by a hydrogen-bond between NH of Glu11 and the carbonyl group of Gly8. The low temperature coefficient of NH(Glu11) and, in particular, the observation of a medium range NOE between H alpha (A9) and NH(E11) corroborate the existence of a beta-turn in this region. Although spectral overlap prevents a precise conclusion with regard to the type of beta-turn present, there is some evidence that it might be type II.

Conformational analysis of the type II and type III collagen alpha-1 chain N-telopeptides by 1H-NMR spectroscopy and restrained molecular mechanics calculations

The type II and type III collagen alpha-1 chain N-telopeptides are a nonadecamer with the sequence pEMAGGFDEKAGGAQLGVMQ-NH2 and a tetradecamer with the sequence pEYEAYDVKSGVAGG-NH2, respectively. Their conformations have been studied in CD3OH/H2O (60/40) solution by means of two-dimensional proton nmr spectroscopy. Based on double quantum filtered correlation spectroscopy, total correlation spectroscopy, rotating frame nuclear Overhauser enhancement (ROE) spectroscopy, and nuclear Overhauser enhancement (NOE) spectroscopy experiments, all resonances were assigned and the conformational properties were analyzed in terms of vicinal NH-H alpha coupling constants, sequential and medium-range NOEs (ROEs), and amide proton temperature coefficients. The NOE distance constraints as well as dihedral constraints based on the vicinal NH-H alpha coupling constants were used as input parameters for restrained molecular mechanics, consisting of restrained molecular dynamics and restrained energy minimization calculations. The type II N-telopeptide's conformation is dominated by a fused beta gamma-turn between Phe6 and Ala10, stabilized by three hydrogen bonds and a salt bridge between the side-chain end groups of Glu8 and Lys9. The first 5 amino acids are extended with a much higher degree of conformational freedom. The 2 Gly residues following the turns were found to be highly flexible (hinge-like), leaving the spatial position of the second half of the molecule relative to the fused beta gamma-turn undefined. In the type III telopeptide, a series of sequential NH(i)-NH(i + 1) ROEs were observed between the amino acids Tyr2 and Ser9, indicating that a fraction of the conformational space is helical. However, the absence of medium-range ROEs and the lack of regularity of the effects associated with alpha-helices suggest the presence of a nascent rather than a complete helix.

A proton magnetic resonance study of two synthetic agonist-antagonist pairs of bradykinin analogues

The conformation of two agonist-antagonist pairs of bradykinin (Arg1-Pro2-Pro2-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9) analogues were studied in CD3OH/H2O solution by 1H-nmr techniques. The first agonist peptide studied, D-Arg0-Arg1-Pro2-Hyp3-Gly4-Thi5-Ser6-Pro7- Thi8-Arg9, differs from the bradykinin sequence by the addition of D-Arg0, the replacement of the Phe moieties in positions 5 and 8 by Thi (Thi = beta-(2-thienyl)-L-alanine), and Hyp3 (Hyp = L-4-hydroxy-L-proline) in position 3. In the corresponding antagonist sequence, Pro7 is replaced by D-Phe7. The second agonist-antagonist pair studied does not contain the D-Arg0 residue, which is present only to slow down the rate of metabolism. Based on complete resonance assignments from two-dimensional total correlation spectroscopy and rotating frame nuclear Overhauser effect spectroscopy spectra at 500 MHz, the peptides were analyzed in terms of intraresidue, sequential, and medium-range nuclear Overhauser effects, amide proton temperature coefficients, and vicinal coupling constants. Both agonist peptides show clear evidence for the existence of a type I beta-turn comprising the C-terminal residues Ser6-Pro7-Thi8-Arg9 in fast conformational equilibrium with extended structures throughout. Although the conformational space is dominated by extended structures, the presence of the beta-turn is spectroscopically clearly discernible. The two antagonist peptides, on the other hand, do not show evidence of turn formation but rather the presence of an extended conformation with some irregularities in the N-terminal region of the peptide. While the existence of a turn at the C-terminal end of bradykinin and its analogues with agonist activity has been predicted by empirical calculations and measurements in very apolar solvents, this study, for the first time, provides evidence based on physical data in a polar solvent environment that the turn is present, that it is type I and that it is essential for agonist activity. In the particular solvent used in these studies, the Pro7 to D-Phe7 substitution precluded the formation of the turn for the C-terminal residues of the antagonist.

A sequence-dependent 1H-NMR study on the formation of beta-turns in tetrapeptides containing charged residues

The importance of side-chain charge interactions in the formation of beta-turns was studied. Sixteen protected NAc-tetrapeptide amides were studied, namely the variants of DEKS: NEKS, EEKS, DDKS, DQKS, NQKS, DERS, NERS, EERS, DDRS, NDRS, DQRS, and DKES. Three tetrapeptides--NPDM, NSDM, and NDDS--were also studied as they have a high probability of forming beta-turns, based on statistical predictions. The results indicate that a small proportion of type I beta-turn exists in solutions of DEKS and DERS in methanol/water (60/40), while NEKS has an even smaller population of this turn. The other tetrapeptides are present in solution only in the extended conformation. These results clearly show the importance of the salt bridge between the side chains of K2 and E3 or R2 and E3, as well as the importance of the charge on the side chain of the first residue in stabilizing the beta-turn. The relevance of statistical predictions for beta-turns in short peptides is discussed.

The solution conformation of tubulin-beta(422-434)-NH2 and its Nac-DATADEQG-NH2 fragment based on NMR

The solution conformation of tubulin-beta(422-434)-NH2 (YQQYQDATADEQG-NH2) and its Nac-DATADEQG-NH2 fragment has been studied by two-dimensional 1H-nmr spectroscopy in CD3OH/H2O (90/10 v/v) at neutral and low pH. The 13 amino acid peptide is a segment of the C-terminal region of tubulin, and is directly involved in the selective binding site with microtubule-associated proteins MAP-2 and the tau protein. Based on correlated spectroscopy, total correlation spectroscopy, and rotating frame nuclear Overhauser effect spectroscopy experiments, a complete assignment of all proton resonances was achieved, and the conformation of the backbone could be deduced from coupling constants, NH temperature coefficients, and nuclear Overhauser effects. The spectroscopic evidence indicates that the T8-Q12 section of both molecules forms one complete alpha-helical turn, stabilized by a NH (Q12)-C = O (T8) hydrogen bond. Furthermore, strong pH-dependent backfolding of the E11 side chain to its own NH proton was found. In addition, close proximity between the aromatic side chains of Y1, Y4, and the alpha-helical part, resulting in some substantial chemical shift changes when comparing the entire 13-mer with the octamer, could be explained in terms of a nonclassical kink in the DATA section. The conformational space is dominated by extended structures and the nonextended conformers are only a minor, yet spectroscopically clearly discernible entity. The presence of the alpha-helical region at the C-terminus of the 13-mer is important because binding studies of this peptide with MAP-2 indicate that the D10-E11-Q12-G13 fragment is critical for the binding interaction.

Solution conformation of the type I collagen alpha-2 chain telopeptides studied by 1H and 13C NMR spectroscopy

The high-field 1H and 13C NMR studies of the N- and C-terminal telopeptides of the alpha-2 chain of collagen were carried out in CD3OH/H2O solutions. All proton assignments are based on two-dimensional phase-sensitive COSY and ROESY experiments. The conformation of the N-telopeptide (nonamer) is predominantly extended with a small proportion of the molecules existing in a type I beta turn. The four residues involved in this turn are D3-A4-K5-G6 which is stabilized by a C = O(D3)-NH(G6) hydrogen bond. The C-terminal telopeptide is extended throughout. A model is proposed involving charge-charge and hydrophobic interactions between the extended alpha-2 chain N-telopeptide and the adjacent segments of triple-helix. A similar model is proposed for the C-telopeptide.

A 1H and 13C NMR study on the role of salt-bridges in the formation of a type I beta-turn in N-acetyl-L-Asp-L-Glu-L-Lys-L-Ser-NH2

The conformation of the tetrapeptide N-Acetyl-Asp7-Glu8-Lys9-Ser10-NH2, a fragment of the type I collagen alpha-1 chain N-telopeptide, has been studied by 1H and 13C NMR and circular dichroism spectroscopy. The spectroscopic evidence, based on two-dimensional, phase-sensitive NMR techniques such as COSY, ROESY, proton-carbon shift correlation and selective COLOC, indicates a strong dependence of the conformation on the experimental conditions. In CD3OH/H2O (60/40) at ca. neutral pH the tetrapeptide forms a beta-turn, stabilized by a hydrogen bond between NH(S10) and CO(D7) and a strong salt-bridge between COO-(E8) and NH3+(K9). The beta-turn is type I and appears to coexist with a non-hydrogen-bonded structure. The coexistence of these two conformers is proven by proton NMR data such as NH-NH ROEs, reduced NH-H alpha (E8) coupling constant, NH(E8) low-field shift and the temperature coefficient of NH(S10), whereas the conclusion regarding the salt-bridge is based on 13C results. In the same solvent, at a pH below the pKa of the carboxyl groups, no evidence for a conformation other than extended can be found. In aqueous solution at approximately neutral pH, evidence for the E8-K9 charge interaction is observed, but not for a hydrogen bond anywhere in the molecule.

Solution conformation of the type I collagen alpha-1 chain N-telopeptide studied by 1H NMR spectroscopy

The solution conformation of the type I collagen alpha-1 chain N-telopeptide has been studied by CD and 1H NMR spectroscopy at 600 MHz in CD3OH/H2O (60/40 v/v) and H2O solutions. The 19 amino acids form the N-terminal end of the alpha-1 polypeptide chain. By the combined application of several two-dimensional, phase-sensitive NMR techniques (COSY, RELAY, ROESY), a complete assignment of all proton resonances was achieved, and the conformation of the backbone could be established on the basis of the coupling constant and NOE data. In CD3OH/H2O solutions the spectroscopic evidence clearly indicates that two sections of the molecule (pE1-Y6 and T11-M19) are extended and that the D7-S10 segment forms a beta-turn, stabilized by a hydrogen bond between NH(S10) and CO(D7). The data suggest that the turn is of the type I kind (minor) and that it coexists with an extended structure (major conformer). Interactions between the two extended parts of the peptide were not observed, thus excluding the existence of a beta-sheet. In H2O solution the conformation is significantly different, with no beta-turn, but a completely extended structure is observed.

High-field NMR and circular dichroism solvent-dependent conformational studies of the bradykinin C-terminal tetrapeptide Ser-Pro-Phe-Arg

The conformational properties of the tetrapeptide Ser1-Pro2-Phe3-Arg4, the C-terminal fragment of the nonapeptide hormone bradykinin, have been studied by circular dichroism and two-dimensional NMR techniques. Measurements of coupling constants, NH temperature dependence rates and nuclear Overhauser effects (performed with rotating frame nuclear Overhauser spectroscopy, ROESY) in H2O and CD3OH/D2O (80/20, v/v) reveal different conformations in the corresponding solvent. In aqueous solution the molecule exists in a random conformation or as an average of several conformations in rapid exchange. In CD3OH/D2O, however, the conformation is well-defined. The backbone of the peptide is extended, and the side-chains of Phe3 and Arg4 exhibit unusual rigidity for a peptide of this size. Evidently, the secondary structure is stabilized by a charge interaction between the guanidino group of Arg4 and the terminal carboxyl group, since experiments at various pH's show clearly that the definition of conformation decreases strongly upon protonation of the carboxyl function. A NH3+(Ser1)-COO-(Arg4) salt bridge, as well as any form of turn stabilized by hydrogen bonds can be ruled out with certainty.

Type I collagen alpha-1 chain C-telopeptide: solution structure determined by 600-MHz proton NMR spectroscopy and implications for its role in collagen fibrillogenesis

The solution conformation of the alpha-1 chain C-telopeptide has been studied by circular dichroism (CD) and 600-MHz 1H NMR spectroscopy in 60% CD3OH/40% H2O solution. The C-telopeptide contains 27 amino acids which form the C-terminal end of the alpha-1 collagen polypeptide chain. By the combined application of various two-dimensional, phase-sensitive NMR techniques (COSY, RELAY, NOESY, ROESY), a nearly complete assignment of all proton resonances was achieved. Furthermore, the backbone conformation could be established, on the basis of coupling constant and NOE data. The spectroscopic evidence indicates that large sections of the peptide exist in a nonrandom, extended conformation and that there are two segments of higher mobility around the two Gly-Gly units in positions 2,3 and 20,21. Despite these hingelike, flexible sections no measurable fold-back of any of the extended parts was evident. On the basis of this structure, a model is proposed for the simultaneous interaction of the C-telopeptide with two adjacent collagen triple helices within the growing collagen fibril.

An NMR study of the conformations of N-terminal substance P fragments and antagonists

Three N-terminal fragments of the neurotransmitter Substance P as well as two antagonist heptapeptides containing D-amino-acid residues were studied using different 1D and 2D NMR techniques. Total nonexchangeable 1H-NMR assignments were carried out in D2O and the NH protons were assigned in H2O by means of COSY experiments. The spectral data indicates that there are no preferred conformations for the backbone. The N-terminal tetrapeptide SP1-4-OH exists as a mixture of cis/trans isomers and this effect was studied as a function of pH.

One- and two-dimensional 1H NMR study of the substance P fragment ARG-PRO-Lys-Pro

The Substance P fragment Arg1-Pro2-Lys3-Pro4 (SP1-4) has been extensively investigated by means of proton nuclear magnetic resonance at 400 MHz. The combined application of different 2D techniques and a comparison of SP1-4 with its derivative SP1-4-amide allowed the complete and unambiguous assignment of the proton NMR spectrum. Conformational data obtained from the different NMR parameters are compared with theoretical calculations. The results suggest that SP1-4 exists, at the chosen experimental conditions, as a stretched molecule.

The conformational analysis of substance P analogs using high-field NMR techniques

High-field nuclear magnetic resonance measurements were carried out on substance P fragments SP4-11' [pGlu5]-SP5-11 and [pGlu6]SP6-11 both at 400 and at 500 MHz. A spectral simulation was carried out on two of these peptides and the coupling constants were interpreted in terms of the conformations. The JNH-CHa coupling constants are all approximately 8 Hz, with the exception of glycine, indicating no preferred conformation for the backbone. For the amino acids other than p-Glu, a comparison of the coupling constant data suggests the same relative rotamer populations for the side chains. Proton longitudinal relaxation time data were measured for all three peptides and support the above conclusions.