The relationship between amide proton chemical shifts and secondary structure in proteins

Summary The parameters for HN chemical shift calculations of proteins have been determined using data from high-resolution crystal structures of 15 proteins. Employing these chemical shift calculations for HN protons, the observed secondary structure chemical shift trends of HN protons, i.e., upfield shifts on helix formation and downfield shifts on -sheet formation, are discussed. Our calculations suggest that the main reason for the difference in NH chemical shifts in helices and sheets is not an effect from the directly hydrogen-bonded carbonyl, which gives rise to downfield shifts in both cases, but arises from an additional upfield shift predicted in helices and originating in residues i-2 and i-3. The calculations also explain the well-known relationship between amide proton shifts and hydrogen-bond lengths. In addition, the HN chemical shifts of the distorted amphipathic helices of the GCN4 leucine zipper are calculated and used to characterise the solution structure of the helices. By comparing the calculated and experimental shifts, it is shown that in general the agreement is good between residues 15 and 28. The most interesting observation is that in the N-terminal half of the zipper, although both calculated and experimental shifts show clear periodicity, they are no longer in phase. This suggests that for the N-terminal half, in the true average solution structure the period of the helix coil is longer by roughly one residue compared to the NMR structures.     

Determination of handedness of DNA double helices from NOE difference spectra: the structure of poly(dG-dC).poly(dG-dC) in low salt

Combined use of shielding constant computations, measurements of chemical shifts and NOE studies reveal that poly(dG-dC).(poly)dG-dC) in low salt solutions exist as a right-handed B-DNA double helix described by Gupta, Dhingra, Sarma, Sarma, Rajagopalan and Sasisekharan, J. Biomole. Str. Dyn. 1. 395, 1983. We present a simple and direct method to determine the handedness of DNA double helices from NOE difference spectra. This method takes advantage of the NOE between base protons and the H2'H2" sugar protons; and in the difference NOE spectra in the H2'H2" region the signatures of the right and left-handed helices become imprinted.     

Solution structure of RNA duplexes containing alternating CG base pairs: NMR study of r(CGCGCG)2 and 2'-O-Me(CGCGCG)2 under low salt conditions.

Structures of r(CGCGCG)2 and 2'-O-Me(CGCGCG)2 have been determined by NMR spectroscopy under low salt conditions. All protons and phosphorus nuclei resonances have been assigned. Signals of H5'/5" have been assigned stereospecifically. All 3JH,H and 3JP,H coupling constants have been measured. The structures were determined and refined using an iterative relaxation matrix procedure (IRMA) and the restrained MD simulation. Both duplexes form half-turn, right-handed helices with several conformational features which deviate significantly from a canonical A-RNA structure. Duplexes are characterised as having C3'-endo sugar pucker, very low base-pair rise and high helical twist and inclination angles. Helices are overwound with <10 bp per turn. There is limited inter-strand guanine stacking for CG steps. Within CG steps of both duplexes, the planes of the inter-strand cytosines are not parallel while guanines are almost parallel. For the GC steps this pattern is reversed. The 2'-O-methyl groups are spatially close to the 5'-hydrogens of neighbouring residues from the 3'-side and are directed towards the minor groove of 2'-O-Me(CGCGCG)2 forming a hydrophobic layer. Solution structures of both duplexes are similar; the effect of 2'-O-methylation on the parent RNA structure is small. This suggests that intrinsic properties imposed by alternating CG base pairs govern the overall conformation of both duplexes.     

Peptide/protein structure analysis using the chemical shift index method: upfield alpha-CH values reveal dynamic helices and alpha L sites.

The alpha-CH shifts observed by 1H NMR for medium-sized peptides and for an unusual small protein, herein, which has a high density of alpha L conformations within its 43 residue length, reveal that the recently introduced chemical shift index (CSI) analysis places short dynamic helices (alpha R) and alpha L residues in the same category as stable helices. The method appears to be a promising addition to the arsenal of methods for peptide structure analysis and is clearly not limited to rigid protein systems.     

Two-dimensional proton nuclear magnetic resonance investigation of the synthetic deoxyribonucleic acid decamer d(ATATCGATAT)2

In this study two-dimensional NMR techniques (COSY and NOESY) have been used in conjunction with one-dimensional NMR results to complete the assignment of the proton NMR spectrum of the double-stranded DNA decamer, d(ATATCGATAT)2, and to obtain qualitative information about numerous interproton distances in this molecule and some limited information about conformational dynamics. COSY and NOESY measurements have been combined to systematically assign many of the resonances from the H1' and H2',2" sugar protons to specific nucleotides in the double helix. This method relies on the fact that sugar protons within a specific nucleotide are scalar coupled and that base protons (AH8, GH8, TH6, and CH6) in right-handed helices can interact simultaneously with their own H2',2" sugar protons and those of the adjacent (5'-3') nucleotide attached to its 5' side (i.e., XpA not ApX). A COSY experiment is used to identify sugar resonances within a residue whereas the NOESY experiment allows the neighboring sugar to be connected (linked). The CH5 and CH6 resonances in the spectrum can immediately be identified by the COSY experiment. The methyl protons of thymine residues exhibit strong through-space interbase interactions both with their own TH6 proton and with AH8 proton on the adjacent (5'-3') adenine residue. These interactions are used both to make assignments of the spectra and to establish that the thymine methyl groups are in close proximity to the AH8 protons of adjacent adenine residues [Feigon, J., Wright, J. M., Leupin, W., Denny, W. A., & Kearns, D. R. (1982) J. Am. Chem. Soc. 104, 5540].(ABSTRACT TRUNCATED AT 250 WORDS)     

Periodicity of amide proton exchange rates in a coiled-coil leucine zipper peptide.

The two-stranded coiled-coil motif, which includes leucine zippers, is a simple protein structure that is well suited for studies of helix-helix interactions. The interaction between helices in a coiled coil involves packing of "knobs" into "holes", as predicted by Crick in 1953 and confirmed recently by X-ray crystallography for the GCN4 leucine zipper [O'Shea, E.K., Klemm, J.D., Kim, P.S., & Alber, T. (1991) Science 254, 539]. A striking periodicity, extending over six helical turns, is observed in the rates of hydrogen-deuterium exchange for amide protons in a peptide corresponding to the leucine zipper of GCN4. Protons at the hydrophobic interface show the most protection from exchange. The NMR chemical shifts of amide protons in the helices also show a pronounced periodicity which predicts a short H-bond followed by a long H-bond every seven residues. This variation was anticipated in 1953 by Pauling and is sufficient to give rise to a local left-handed superhelical twist characteristic of coiled coils. The amide protons that lie at the base of the "hole" in the "knobs-into-holes" packing show slow amide proton exchange rates and are predicted to have short H-bond lengths. These results suggest that tertiary interactions can lead to highly localized, but substantial, differences in stability and dynamics within a secondary structure element and emphasize the dominant nature of packing interactions in determining protein structure.     

Proton-nuclear-magnetic-resonance study of the conformation of neurotoxin II from Middle-Asian cobra (Naja naja oxiana) venom.

A proton nuclear magnetic resonance (NMR) study at 100 and 300 MHz of neurotoxin II from the venom of Middle-Asian cobra Naja naja oxiana has been performed in 2H2O and H2O solutions. By means of chemical modification and double resonance all the aromatic residue resonances have been assigned. From the NMR titration curves, pK values of histidine 4 and histidine 31 residues have been determined. For one of the two neighbouring tryptophan residues pH dependence (in the 2-8-pH range) of the chemical shifts of indole protons has been revealed. According to the different sensitivity of the linewidth of indole NH resonances to pH in H2O solution, the accessibility of each of the tryptophan residues has been estimated. Temperature dependence has been observed for the linewidth of the aromatic resonances of the tyrosine 24 residue. Deuterium exchange rates have been measured for amide protons as well as for C(2)H histidine resonances. The NMR data obtained have allowed the conclusions to be made that the two histidine residues and one of the tryptophan residues should be localized on the surface of the protein globule, that arginine residues should be present in the environment of histidine 4, that histidine 31 and the buried tryptophan are possibly localized in close spatial proximity and that the side chain of tyrosine 24 is buried within the protein globule.     

OnionTree XML: A Format to Exchange Gene-Related Probabilities

Abstract

Combined use of shielding constant computations, measurements of chemical shifts and NOE studies reveal that poly(dG-dC)?(poly)dG-dC) in low salt solutions exist as a right- handed B-DNA double helix described by Gupta, Dhingra, Sarma, Sarma, Rajagopalan and Sasisekharan, J. Biomole. Str. Dyn. 1, 395, 1983. We present a simple and direct method to determine the handedness of DNA double helices from NOE difference spectra. This method takes advantage of the NOE between base protons and the H2′H2” sugar protons; and in the difference NOE spectra in the H2′H2” region the signatures of the right and left-handed helices become imprinted.     

Secondary-structure dependent chemical shifts in proteins

Chemical shift data have been collected on eight proteins that have the same conformation in solution as in their crystal structures. Ring-current shifts have been calculated and subtracted from the exerimentally measured shifts, to leave shifts that depend only on local conformation. Overall, the shifts show an approximately normal distribution with no appreciable skewness, thus confirming that ring-current shifts have the overall effect of skewing the distribution to high field. In helices, NH and C(alpha)H have a high significant tendency to resonate to high field, whereas they resonate to low field in beta-sheets. Side-chain protons resonate slightly to high field in beta-sheets. Chemical shift distributions are narrowest for side-chain protons, and widest for amide protons. When only slowly exchanging amide protons are considered, the high field shift for amide protons in helices is more pronounced, but there is only a small difference in sheets. C(alpha)H signals at the N-terminal end of helices tend to resonate to higher field than those at the C-terminal end, whereas for NH signals it is the C-terminal end that resonates to higher field. There is no significant effect of position within the helix on side-chain signals, implying that the helix dipole has little effect on shifts within the helix.     

Persistence of the alpha-helix stop signal in the S-peptide in trifluoroethanol solutions

alpha-Helix formation in the S-peptide (residues 1-19 of ribonuclease A) was studied in detail by use of two-dimensional 1H nuclear magnetic resonance to monitor the effects of 2,2,2-trifluoroethanol (TFE) at 0 degrees C and pH* 2.07. TFE stabilizes the S-peptide alpha-helix. Helix formation by a particular amino acid was monitored by the chemical shifts of the C alpha, C beta, and C gamma protons while increasing the concentration of TFE: large changes in chemical shift of a particular residue indicate that it is induced to go helical, whereas small chemical shift changes indicate little helix formation. Residues Thr-3 to Met-13 undergo chemical shift changes consistent with helix formation, whereas the other residues do not. Earlier work [Kim, P. S., & Baldwin, R. L. (1984) Nature 307, 329-334] reported that residues Thr-3 to His-12 become helical in aqueous solution. The existence of a "helix stop signal" was inferred from this behavior. We thus conclude that this helix stop signal persists in TFE solutions.     

A theoretical study oh the effect of "bound" water on the proton chemical shifts of the nucleic acid bases.

Computations are performed on the proton chemical shifts due to hydrogen bonding between the purine and pyrimidine bases of the nucleic acids and water molecules of their first hydration shell. The water molecules should produce measurable shifts essentially for protons of the bases located close to the site of interaction. For the imino protons of the bases G-N1H and U-N3H participating in hydrogen bonding, the calculated delta delta is larger for the interaction of a base with a complementary base than for its interaction with water. Base pairing will thus produce a downfield shift in water but the measured delta delta due to pairing in this solvent will be smaller than in an inert solvent. Also, the chemical shift difference between G-N1H and U-N3H in water will be larger if the molecules are engaged in pairs than if they are not.     

Hydroxy protons in conformational study of a Lewis b tetrasaccharide derivative in aqueous solution by NMR spectroscopy

The 1H NMR chemical shifts, vicinal coupling constants, temperature coefficients, and exchange rates of the hydroxy protons of a Lewis b tetrasaccharide derivative, alpha-L-Fucp-(1 --> 2)-beta-D-Galp-(1 --> 3)[alpha-L-Fucp-(1 --> 4)]-beta-D-GlcpNAc-1-O(CH2)2NHCOCHCH2, have been measured in aqueous solution. The data did not show any evidence for persistent hydrogen bonds participating in the stabilization of the structure. While most of the hydroxy proton signals have chemical shifts similar to those of the corresponding methyl glycosides, four of them, O(3)H, O(4)H, and O(6)H of Galp, and O(2)H of the Fucp linked to GlcpNAc, exhibit large upfield shifts. This shielding effect has been attributed to the orientation of the hydroxy protons toward the amphiphilic region constituted by the hydroxy groups of the Galp residue and mainly the ring and methyl hydrogens of the Fucp unit attached to the GlcpNAc. The close face to face stacking interaction between the Fucp linked to the GlcpNAc and the Galp residues, as well as the steric interaction between the Fucp linked to the Galp and the GlcpNAc are confirmed by the additional inter-residue NOEs of the exchangeable protons in sugar units which are not directly connected.     

Assignment of the proton Nmr chemical shifts of the T-N3H and G-N1H proton resonances in isolated AT and GC Watson-Crick base pairs in double-stranded deoxy oligonucleotides in aqueous solution

The 300-MHz proton nmr spectra (between 11 and 14 ppm) of a series of double-stranded deoxy oligonucleotides of known sequence have been recorded in H₂O solution. These resonances have been assigned to the G? N₁H and T? N₃H protons of specific base pairs from an evaluation of the temperature dependence of the ring NH linewidths and from the selective ring NH chemical shift changes on actinomycin-D binding. The deoxy oligonucleotides exist predominantly in the DNA-B conformation as evaluated from antibiotic binding studies. Ring-current calculations have been utilized to evaluate the up-field shifts of the G? N₁H and T? N₃H protons in Watson-Crick base pairs due to the ring currents from the pyrimidine and purine rings of nearest neighbor base pairs in regular DNA-B- and RNA-A-type helices. The perturbations on these up-field ring-current contributions that arise from twisting and tilting a base pair adjacent to the ring NH under study have been evaluated and found to change the calculated chemical shift by ±0.6 ppm for twist and tilt distortions of <30°C in a single adjacent base pair. A knowledge of the experimentally assigned ring NH chemical shifts of specific base pairs in known sequences of double-stranded deoxy oligonucleotides coupled with the ring-current tables for the DNA-B helical structure permit the assignment of 13.6 ± 0.1 ppm and 14.6 ± 0.2 ppm for the G? N₁H proton of an isolated GC base pair and the T? N₃H proton of an isolated AT base pair, respectively.     

1H nuclear magnetic resonance titration curves and microenvironments of aromatic residues in bovine pancreatic ribonuclease A

The aromatic region of the NMR spectrum of bovine pancreatic ribonuclease A was analyzed in order to clarify the nature of the microenvironments surrounding the individual histidine, tyrosine, and phenylalanine residues and the interactions with inhibitors. The NMR titration curves of ring protons of six tyrosine and three phenylalanine residues as well as four histidine residues were determined at 37 degrees C between pH 1.5 and pH 11.5 under various conditions. The titration curves were analyzed on the basis of a scheme of a simple proton dissociation sequence and the most probable values were obtained for the macroscopic pK values and intrinsic chemical shifts. The microenvironments surrounding the residues and the effects of inhibitors are discussed on the basis of these results. Based on the titration curves of ring protons, the six tyrosine residues were classified into the following four groups: (1) titratable and different chemical shifts for C(delta) and C(epsilon) protons (two tyrosine residues), (2) titratable but similar chemical shifts for C(delta) and C(epsilon) protons (two tyrosine residues), (3) not titratable and different chemical shifts for C(delta) and C(epsilon) protons (one tyrosine residues), and (4) not titratable and similar chemical shifts for C(delta) and C(epsilon) protons (one tyrosine residue). The resonance signals of ring protons were tentatively assigned to tyrosine and phenylalanine residues. The NMR titration curves of His-48 ring protons were continuous in solution containing 0.2 M sodium acetate but were discontinuous in solution containing 0.3 M NaCl because the NMR signals disappeared at pH values between 5 and 6.5. The effects of addition of formate, acetate, propionate, and ethanol were investigated in order to elucidate the mechanism of the continuity of the titration curves of His-48 in the presence of acetate ion. The NMR signal of His-48 C(2) protons was observed at pH 6 in the presence of acetate and propionate ions but was not observed in the presence of formate ion or ethanol. This indicated that both the alkyl chain and the anionic carboxylate group are necessary for the continuity of the titration curves of His-48 ring protons. Based on the results, the mechanism of the effects of acetate ion is discussed.     

Hydrophobic clustering in nonnative states of a protein: interpretation of chemical shifts in NMR spectra of denatured states of lysozyme.

Chemical shifts of resonances of specific protons in the 1H NMR spectrum of thermally denatured hen lysozyme have been determined by exchange correlation with assigned native state resonances in 2D NOESY spectra obtained under conditions where the two states are interconverting. There are subtle but widespread deviations of the measured shifts from the values which would be anticipated for a random coil; in the case of side chain protons these are virtually all net upfield shifts and it is shown that this may be the averaged effect of interactions with aromatic rings in a partially collapsed denatured state. In a very few cases, notably that of two sequential tryptophan residues, it is possible to interpret these effects in terms of specific, local interresidue interactions. Generally, however, there is no correlation with either native state shift perturbations or with sequence proximity to aromatic groups. Diminution of most of the residual shift perturbations on reduction of the disulfide cross-links confirms that they are not simply effects of residues adjacent in the sequence. Similar effects of chemical denaturants, with the disulfides intact, demonstrate that the shift perturbations reflect an enhanced tendency to side chain clustering in the thermally denatured state. The temperature dependences of the shift perturbations suggest that this clustering is noncooperative and is driven by small, favorable enthalpy changes. While the extent of conformational averaging is clearly much greater than that observed for a homologous protein, alpha-lactalbumin, in its partially folded "molten globule" state, the results clearly show that thermally denatured lysozyme differs substantially from a random coil, principally in that it is partially hydrophobically collapsed.     

Resonance assignments of non-exchangeable protons in B type DNA oligomers, an overview.

The chemical shifts of 1H resonances of non exchangeable protons (except H5', H5" and adenine H2) of over six hundred nucleotides have been collected. The influence which the base of the nucleotide itself as well as the bases on its 5' and 3' side exert on the chemical shifts of the various resonances has been investigated. Most of the resonances appear to be predominantly influenced by only one base. For H2', H2", H3', H4' and H6/H8 this is the base of the central nucleotide, for H5(C) and CH3(T) it is the one on the 5' side and for H1' it is the one on the 3' side. Chemical shift distribution profiles are presented which allow an estimation of the probability of finding a particular resonance at a particular position in the spectrum.     

1H n.m.r. parameters of the N-terminal 19-residue S-peptide of ribonuclease in aqueous solution

The 1H n.m.r. chemical shifts and the spin-spin coupling constants of the N-terminal 19-residue S-peptide of ribonuclease A have been measured in a 10 mM solution in D2O, pD 3.0, 27 degrees, at 300 MHz. The titration parameters for end groups Lys-1 and Ala-19 and side chains Lys-1, Glu-2, Lys-7, Glu-9, Arg-10, His-12 and Asp-14 have been determined at 90 MHz. An assignment of observed signals to individual residue protons based upon characteristic shifts, spectral analysis, double resonance, titration shifts and comparison with the spectrum of C-peptide (N-terminal 13-residue) is proposed. Differences in the observed chemical shifts, pKa's and titration shifts with reference to those proposed as "random coil" parameters are not large enough to assume the existence of a significant population of secondary structure in the conditions studied. The H alpha chemical shifts differences can be accounted for by the Phe-8 phenyl ring current for an extended peptide backbone conformation and appropriate values for the torsion angles chi 1 Phe-8 and chi 2 Phe-8.     

360 MHz PMR studies on the involvement of the Y-nucleoside in the conformation of 2''-OMeGpApApYpAppsi from torula yeast tRNAphe.

360 MHz measurements of chemical shifts, 3J1'-2', and T1 as a function of temperature for various protons of the hexanucleotide 2'-OMeGpApApYpAppsi from torula yeast tRNAphe have revealed a unique involvement of the Yt base in the structure and conformation of this oligonucleotide. Whereas the adenosine residues in the anticodon triplet are relatively stable to temperature increase, the Yt readily undergoes destacking and a change in ribose conformation. The destacking most likely involves a torsional displacement of the Yt base occasioned by a rotation of the phosphate-ribose backbone. The possible relevance of this unusual behavior to the influence of the Yt residue in tRNA function in protein biosynthesis is discussed.     

Analysis of 1H chemical shifts in DNA: Assessment of the reliability of 1H chemical shift calculations for use in structure refinement

The reliability of ¹H chemical shift calculations for DNA is assessed by comparing the experimentally and calculated chemical shifts of a reasonably large number of independently determined DNA structures. The calculated chemical shifts are based on semiempirical relations derived by Giessner-Prettre and Pullman [(1987) Q. Rev. Biophys., 20, 113–172]. The standard deviation between calculated and observed chemical shifts is found to be quite small, i.e. 0.17 ppm. This high accuracy, which is achieved without parameter adjustment, makes it possible to analyze the structural dependencies of chemical shifts in a reliable fashion. The conformation-dependent ¹H chemical shift is mainly determined by the ring current effect and the local magnetic anisotropy, while the third possible effect, that of the electric field, is surprisingly small. It was further found that for a double helical environment, the chemical shift of the sugar protons, H2 to H5, is mainly affected by the ring current and magnetic anisotropy of their own base. Consequently, the chemical shift of these sugar protons is determined by two factors, namely the type of base to which the sugar ring is attached, C, T, A, or G, and secondly by the -angle. In particular, the H2 shift varies strongly with the -angle, and strong upfield H2 shifts directly indicate that the -angle is in the syn domain. The H1 shift is not only strongly affected by its own base, but also by its 3-neighboring base. On the other hand, base protons, in particular H5 of cytosine and methyl protons of thymine, are affected mainly by the 5-neighboring bases, although some effect (0.2 ppm) stems from the 3-neighboring base. The H2 protons are mainly affected by the 3-neighboring base. As a result of these findings a simple scheme is proposed for sequential assignment of resonances from B-helices based on chemical shifts.     

Conformational analyses of sandostatin analogs containing stereochemical changes in positions 6 or 8

We report the conformational analysis by 1H nmr in DMSO and computer simulations involving distance geometry and molecular dynamics simulations of analogs of the cyclic octapeptide D-Phe1-c[Cys2-Phe3-D-Trp4-Lys5-Thr6-Cys 7]-Thr8-ol (sandostatin, octreotide). The analogs D-Phe1-c[Cys2-Phe3-D-Trp4-Lys5-Xaa6-Cys 7]-Xbb8-NH2 (Xaa = allo-Thr, D-allo-Thr, D-beta-Hyv, beta-Hyv, D-Thr, and Xbb = Thr or Xaa = Thr and Xbb = allo-Thr, D-allo-Thr, beta-Hyv, D-Thr) contain stereochemical changes in the Thr residues in positions 6 and 8, which allow us to investigate the influence of the stereochemistry within these residues on conformation and binding affinity. The molecular dynamics simulations provide insight into the conformational flexibility of these analogs. The compounds with (S)-configuration at the C(alpha) of residue 6 adopt beta-sheet structures containing a type II' beta-turn with D-Trp in the i+1 position, and these conformations are "folded" about residues 6 and 3. The structures are very similar to those observed for sandostatin, and the disulfide bridge results in a close proximity of the H(alpha) protons of residues 7 and 2, which confirms earlier observations that a disulfide bridge is a good mimic for a cis peptide bond. The compounds with (R)-configuration at the C(alpha) of residue 6 adopt considerably different backbone conformations. The structures observed for these analogs contain either a beta-turn about residue Lys and Xaa6 or a gamma-turn about the Xaa6 residue. These compounds do not exhibit significant binding to the somatostatin receptors, while the compounds with (S) configuration in position 6 bind potently to the sst2, 3, and 5 receptors. The nmr spectra of analogs with (R) or (S) configuration at the C(alpha) of residue 8 are strikingly similar to each other. We have demonstrated that the chemical shifts of protons of residues 3, 4, 5, and 6, which are part of the type II' beta-turn, and especially the effect on the Lys gamma-protons are considerably different in active molecules as compared to inactive analogs. Since the presence of a type II' beta-turn is crucial for the binding to the receptors, the chemical shifts, the amide temperature coefficients of the Thr residue and the medium strength NOE between LysNH and ThrNH can be extremely useful as an initial screening tool to separate the active molecules from inactive analogs.