Application of 2D and 3D NMR experiments to the conformational study of a diantennary oligosaccharide

Summary By the application of homonuclear 3D NOE-HOHAHA and heteronuclear 3D HMQC-NOE experiments in studies of complex oligosaccharides. NOEs can be investigated which are hidden in conventional 2D NOE spectra. In the 3D NOE-HOHAHA spectrum ₃ cross sections were considered to be the most suitable for assignment of NOEs. Alternatively, these cross sections could be measured separately in selective 2D HOHAHA-NOE spectroscopy. The advantages and limitations of the 2D alternative are compared with those of the 3D NOE-HOHAHA approach. In 3D HMQC-NOE spectroscopy the larger chemical shift displacement of the carbon spectrum with respect to the proton spectrum can be used to unmask NOEs hidden in the bulk region. If the extra proton dimension is not needed, 2D HMQC-NOE is a good alternative.The suitability of 2D and 3D NOE-HOHAHA and HMQC-NOE experiments for the estimation of proton-proton distances is demonstrated by comparing the results of these experiments on a diantennary asparagine-linked oligosaccharide with those of a conventional 2D NOE experiment. NOEs identified in the 2D and 3D NOE-HOHAHA as well as HMQC-NOE experiments, so far not identified or not quantified in 2D NOE experiments, are discussed in relation to each glycosidic linkage. The flexibility of the Man(1-3)Man linkage is demonstrated, confirming the existence of an ensemble of conformations for this linkage.     

An improved ultrafast 2D NMR experiment: Towards atom-resolved real-time studies of protein kinetics at multi-Hz rates

Multidimensional NMR spectroscopy is a well-established technique for the characterization of structure and fast-time-scale dynamics of highly populated ground states of biological macromolecules. The investigation of short-lived excited states that are important for molecular folding, misfolding and function, however, remains a challenge for modern biomolecular NMR techniques. Off-equilibrium real-time kinetic NMR methods allow direct observation of conformational or chemical changes by following peak positions and intensities in a series of spectra recorded during a kinetic event. Because standard multidimensional NMR methods required to yield sufficient atom-resolution are intrinsically time-consuming, many interesting phenomena are excluded from real-time NMR analysis. Recently, spatially encoded ultrafast 2D NMR techniques have been proposed that allow one to acquire a 2D NMR experiment within a single transient. In addition, when combined with the SOFAST technique, such ultrafast experiments can be repeated at high rates. One of the problems detected for such ultrafast protein NMR experiments is related to the heteronuclear decoupling during detection with interferences between the pulses and the oscillatory magnetic field gradients arising in this scheme. Here we present a method for improved ultrafast data acquisition yielding higher signal to noise and sharper lines in single-scan 2D NMR spectra. In combination with a fast-mixing device, the recording of ¹H–¹⁵N correlation spectra with repetition rates of up to a few Hertz becomes feasible, enabling real-time studies of protein kinetics occurring on time scales down to a few seconds.     

Protein hydration studied with homonuclear 3D1H NMR experiments

Summary Homonuclear 3D¹H NOESY-TOCSY and 3D¹H ROESY-TOCSY experiments were used to resolve and assign nuclear Overhauser effect (NOE) cross peaks between the water signal and individual polypeptide proton resonances in H₂O solutions of the basic pancreatic trypsin inhibitor. Combined with a novel, robust water-suppression technique, positive and negative intermolecular NOEs were detected at 4°C. The observation of positive NOEs between water protons and protein protons enables more precise estimates of the very short residence times of the water molecules in the hydration sites on the protein surface.     

Computer-assisted assignment of multidimensional NMR spectra of proteins: Application to 3D NOESY-HMQC and TOCSY-HMQC spectra

Summary An algorithm based on the technique of combinatorial minimization is used for the semi-automated assignment of multidimensional heteronuclear spectra. The program (ALFA) produces the best assignment compatible with the available input data. Even partially misleading or missing data do not seriously corrupt the final assignment. Ambiguous sequences of the possible assignment and all alternatives are indicated. The program can also use additional non-spectroscopic data to assist in the assignment procedure. For example, information from the X-ray structure of the protein and/or information about the secondary structure can be used. The assignment procedure was tested on spectra of mucous trypsin inhibitor, a protein of 107 residues.     

A general method for assigning NMR spectra of denatured proteins using 3D HC(CO)NH-TOCSY triple resonance experiments

Summary A general approach for assigning the resonances of uniformly ¹⁵N- and ¹³C-labeled proteins in their unfolded state is presented. The assignment approach takes advantage of the spectral dispersion of the amide nitrogen chemical shifts in denatured proteins by correlating side chain and backbone carbon and proton frequencies with the amide resonances of the same and adiacent residues. The ¹H resonances of the individual amino acid spin systems are correlated with their intraresidue amide in a 3D ¹⁵N-edited ¹H, ¹H-TOCSY-HSQC experiment, which allows the spin systems to be assigned to amino acid type. The spin systems are then linked to the adjacent i-1 spin system using the 3D H(C)(CO)NH-TOCSY experiment. Complete ¹³C assignments are obtained from the 3D (H)C(CO)NH-TOCSY experiment. Unlike other methods for assigning denatured proteins, this approach does not require previous knowledge of the native state assignments or specific interconversion rates between the native and denatured forms. The strategy is demonstrated by assigning the ¹H, ¹³C, and ¹⁵N resonances of the FK506 binding protein denatured in 6.3 M urea.     

Minimizing the effects of radio-frequency heating in multidimensional NMR experiments

Summary Application of radio-frequency power in multidimensional NMR experiments can significantly increase the sample temperature compared to that of the surrounding gas flow. Radio-frequency heating effects become more severe at higher magnetic field strengths and ionic strengths. The effects are particularly noticeable for experiments that utilize ¹H and/or ¹³C isotropic mixing and broadband decoupling. If radio-frequency power is applied during the systematically increasing evolution period t₁, the sample temperature can change with t₁ and thereby cause line-shape distortions. Such distortions are easily avoided by ensuring that the average radio-frequency power remains constant during the entire experiment.     

Pseudo-3D NMR spectroscopy: Application to oligo- and polysaccharides

Summary Several pseudo-3D NMR experiments are proposed for removal of overlaps in 1D ¹H NMR spectra. A selective pulse and a chemical-shift-selective filter are used for double selection of the magnetization during the course of the pulse sequence. Different polarization transfer mechanisms are combined into pseudo-3D COSY-RELAY, COSY-TOCSY, COSY-NOESY, COSY-ROESY, RELAY-NOESY, RELAY-ROESY, RELAY-RELAY and RELAY-TOCSY experiments. The techniques are illustrated on oligo- and polysaccharide samples.     

Recent progress in heteronuclear long-range NMR of complex carbohydrates: 3D H2BC and clean HMBC

The new NMR experiments 3D H2BC and clean HMBC are explored for challenging applications to a complex carbohydrate at natural abundance of ¹³C. The 3D H2BC experiment is crucial for sequential assignment as it yields heteronuclear one- and two-bond together with COSY correlations for the ¹H spins, all in a single spectrum with good resolution and non-informative diagonal-type peaks suppressed. Clean HMBC is a remedy for the ubiquitous problem of strong coupling induced one-bond correlation artifacts in HMBC spectra of carbohydrates. Both experiments work well for one of the largest carbohydrates whose structure has been determined by NMR, not least due to the enhanced resolution offered by the third dimension in 3D H2BC and the improved spectral quality due to artifact suppression in clean HMBC. Hence these new experiments set the scene to take advantage of the sensitivity boost achieved by the latest generation of cold probes for NMR structure determination of even larger and more complex carbohydrates in solution.     

Application of homonuclear 3D NMR experiments and 1D analogs to study the conformation of sialyl Lewisx bound to E-selectin

The conformation of the sialyl Lewis ^x tetrasaccharidebound to E-selectin was previously determined from transfer NOE (trNOE)experiments in conjunction with a distance-geometry analysis. However, theorientation of the tetrasaccharide ligand in the binding site of E-selectinis still unknown. It can be predicted that the accurate quantitativeanalysis of all trNOEs, including those originating from spin diffusion, isone key to analyze the orientation of sialyl Lewis^x in thebinding pocket of E-selectin. Therefore, we applied homonuclear 3D NMRexperiments and 1D analogs to obtain trNOEs that could not unambiguously beassigned from previous 2D trNOESY spectra, due to severe resonance-signaloverlap. A 3D TOCSY-trNOESY experiment, a 1D TOCSY-trNOESY experiment, and a1D trNOESY-TOCSY experiment of the sialyl Lewis^x/E-selectincomplex furnished new interglycosidic trNOEs and provided additionalinformation for the interpretation of trNOEs that have been describedbefore. A 2D trROESY spectrum of the sialyl Lewis^x/E-selectincomplex allowed one to identify the amount of spin-diffusion contributionsto trNOEs. Finally, an unambiguous assignment of all trNOEs, and an analysisof spin-diffusion pathways, was obtained, creating a basis for aquantitative analysis of trNOEs in the sialylLewis^x/E-selectin complex.     

Reconstruction of the three-dimensional NMR spectrum of a protein from a set of plane projections

Three-dimensional protein NMR spectra can be obtained significantly faster than by traditional methods by a projection-reconstruction procedure related to X-ray tomography. First, two orthogonal projections are acquired in quick two-dimensional experiments with the evolution parameters t₁ or t₂ set to zero. These projections define a three-dimensional lattice; all cross-peaks must lie on this lattice but not all lattice points are occupied. A third experiment with t₁ and t₂ incremented simultaneously and in a fixed ratio, generates a projection onto a tilted plane and thus establishes the positions of all the cross-peaks unambiguously. This projection-reconstruction technique has been tested on the 500 MHz three-dimensional HNCO spectrum of ubiquitin.     

Spin-locked multiple quantum coherence for signal enhancement in heteronuclear multidimensional NMR experiments

Summary For methine sites the relaxation rate of ¹³C-¹H two-spin coherence is generally slower than the relaxation rate of the individual ¹³C and ¹H single spin coherences. The slower decay of two-spin coherence can be used to increase the sensitivity and resolution in heteronuclear experiments, particularly those that require correlation of H and C chemical shifts. To avoid dephasing of the two-spin coherence caused by ¹H-¹H J-couplings, the ¹H spin is locked by the application of a weak rf field, resulting in a spin-locked multiple quantum coherence. For a sample of calcium-free calmodulin, use of the multiple quantum approach yields significant signal enhancement over the conventional constant-time 2D HSQC experiment. The approach is applicable to many multidimensional NMR experiments, as demonstrated for a 3D ¹³C-separated ROESY CT-HMQC spectrum.     

Structural constraints for the Crh protein from solid-state NMR experiments

We demonstrate that short, medium and long-range constraints can be extracted from proton mediated, rare-spin detected correlation solid-state NMR experiments for the microcrystalline 10.4 × 2 kDa dimeric model protein Crh. Magnetization build-up curves from cross signals in NHHC and CHHC spectra deliver detailed information on side chain conformers and secondary structure for interactions between spin pairs. A large number of medium and long-range correlations can be observed in the spectra, and an analysis of the resolved signals reveals that the constraints cover the entire sequence, also including inter-monomer contacts between the two molecules forming the domain-swapped Crh dimer. Dynamic behavior is shown to have an impact on cross signals intensities, as indicated for mobile residues or regions by contacts predicted from the crystal structure, but absent in the spectra. Our work validates strategies involving proton distance measurements for large and complex proteins as the Crh dimer, and confirms the magnetization transfer properties previously described for small molecules in solid protein samples. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Hydration of the partially folded peptide RN-24 studied by multidimensional NMR

Summary Peptide-water interactions of a ribonuclease C-peptide analogue, RN-24 (Suc-AETAAAKFLRAHA-NH₂), which exhibits significant helicity, have been studied in solution using homonuclear 2D and 3D NMR cross-relaxation experiments. Dipolar peptide proton-water proton interactions are indicated by a large number of NOESY-type cross peaks at the H₂O resonance frequency, most of them with opposite sign relative to the diagonal. Some cross peaks arise from intrapeptide cross relaxation to labile protons of histidine, threonine, lysine and arginine side chains. The observed peptide-water interactions are rather uniformly distributed, involving peptide backbone and side chains equally. The data are consistent with rapid fluctuations of the conformational ensemble and the absence of peptide regions that are highly shielded from bulk solvent, even in a peptide that exhibits high propensities for formation of helical secondary structure.     

Assignments and structure determination of the catalytic domain of human fibroblast collagenase using 3D double and triple resonance NMR spectroscopy

We report here the backbone 1HN, 15N, 13C, 13CO, and 1H NMR assignmentsfor the catalytic domain of human fibroblast collagenase (HFC). Three independentassignment pathways (matching 1H, 13C, and 13CO resonances) were used to establishsequential connections. The connections using 13C resonances were obtained fromHNCOCA and HNCA experiments; 13CO connections were obtained from HNCO andHNCACO experiments. The sequential proton assignment pathway was established from a 3D(1H/15N) NOESY-HSQC experiment. Amino acid typing was accomplished using 13C and15N chemical shifts, specific labeling of 15N-Leu, and spin pattern recognition from DQF-COSY. The secondary structure was determined by analyzing the 3D (1H/15N) NOESY-HSQC. A preliminary NMR structure calculation of HFC was found to be in agreement withrecent X-ray structures of human fibroblast collagenase and human neutrophil collagenase aswell as similar to recent NMR structures of a highly homologous protein, stromelysin. Allthree helices were located; a five-stranded -sheet (four parallel strands, one antiparallelstrand) was also determined. -Sheet regions were identified by cross-stranddN and dNN connections and by strong intraresidue dN correlations, and were corroborated byobserving slow amide proton exchange. Chemical shift changes in a selectively 15N-labeledsample suggest that substantial structural changes occur in the active site cleft on the bindingof an inhibitor.     

An efficient strategy for assignment of cross-peaks in 3D heteronuclear NOESY experiments

The question is addressed of how maximal structural NOE data on double labelled proteins can be acquired with a minimal set of NOESY experiments. Two 3D-NOESY spectra are reported which, in concert with other commonly used spectra, provide a convenient strategy for NOE assignment. The 3D CNH-NOESY and 3D NCH-NOESY provide NOE connectivities between amide protons and carbon-bound protons and constitute orthogonal heteronuclear filters which eliminate diagonal signals, considerably improving spectral quality. Two different heteronuclear chemical shift dimensions are recorded in the spectra, thus exploiting the extra dispersion of the heteronucleus and considerably simplifying assignment.     

Spatial integration using a 3D virtual environment with humans

Spatial integration refers to the superimposition of two separate spatial relationships between cues (C1–C2 and C2–C3) by a common linking element (C2). This linkage creates a new spatial relationship between cues that were never paired together (C1–C3). Several authors obtained conflicting results on spatial integration in both humans and animals. Using a dynamic 3D virtual environment, we provide the first clear evidence that humans can integrate two spatial relationships into a new spatial relationship that guides spatial navigation. This research is discussed in light of a spatial version of the temporal coding hypothesis (Savastano and Miller, 1998).     

An accurate and effective FMM-based approach for freehand 3D ultrasound reconstruction

Freehand three-dimensional ultrasound imaging is a highly attractive research area because it is capable of volumetric visualization and analysis of tissues and organs. The reconstruction algorithm plays a key role to the construction of three-dimensional ultrasound volume data with higher image quality and faster reconstruction speed. However, a systematic approach to such problem is still missing. A new fast marching method (FMM) for three-dimensional ultrasound volume reconstruction using the tracked and hand-held probe is proposed in this paper. Our reconstruction approach consists of two stages: bin-filling stage and hole-filling stage. Each pixel in the B-scan images is traversed and its intensity value is assigned to its nearest voxel in the bin-filling stage. For the efficient and accurate reconstruction, we present a new hole-filling algorithm based on the fast marching method. Our algorithm advances the interpolation boundary along its normal direction and fills the area closest to known voxel points in first, which ensure that the structural details of image can be preserved. Experimental results on both ultrasonic abdominal phantom and in vivo urinary bladder of human subject and comparisons with some popular algorithms are used to demonstrate its improvement in both reconstruction accuracy and efficiency.     

HIFI-C: a robust and fast method for determining NMR couplings from adaptive 3D to 2D projections

We describe a novel method for the robust, rapid, and reliable determination of J couplings in multi-dimensional NMR coupling data, including small couplings from larger proteins. The method, “High-resolution Iterative Frequency Identification of Couplings” (HIFI-C) is an extension of the adaptive and intelligent data collection approach introduced earlier in HIFI-NMR. HIFI-C collects one or more optimally tilted two-dimensional (2D) planes of a 3D experiment, identifies peaks, and determines couplings with high resolution and precision. The HIFI-C approach, demonstrated here for the 3D quantitative J method, offers vital features that advance the goal of rapid and robust collection of NMR coupling data. (1) Tilted plane residual dipolar couplings (RDC) data are collected adaptively in order to offer an intelligent trade off between data collection time and accuracy. (2) Data from independent planes can provide a statistical measure of reliability for each measured coupling. (3) Fast data collection enables measurements in cases where sample stability is a limiting factor (for example in the presence of an orienting medium required for residual dipolar coupling measurements). (4) For samples that are stable, or in experiments involving relatively stronger couplings, robust data collection enables more reliable determinations of couplings in shorter time, particularly for larger biomolecules. As a proof of principle, we have applied the HIFI-C approach to the 3D quantitative J experiment to determine N-C′ RDC values for three proteins ranging from 56 to 159 residues (including a homodimer with 111 residues in each subunit). A number of factors influence the robustness and speed of data collection. These factors include the size of the protein, the experimental set up, and the coupling being measured, among others. To exhibit a lower bound on robustness and the potential for time saving, the measurement of dipolar couplings for the N-C′ vector represents a realistic “worst case analysis”. These couplings are among the smallest currently measured, and their determination in both isotropic and anisotropic media demands the highest measurement precision. The new approach yielded excellent quantitative agreement with values determined independently by the conventional 3D quantitative J NMR method (in cases where sample stability in oriented media permitted these measurements) but with a factor of 2–5 in time savings. The statistical measure of reliability, measuring the quality of each RDC value, offers valuable adjunct information even in cases where modest time savings may be realized. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

3D Triple-resonance NMR techniques for the sequential assignment of NH and 15N resonances in 15N- and 13C-labelled proteins

Summary Two new 3D ¹H-¹⁵N-¹³C triple-resonance experiments are presented which provide sequential cross peaks between the amide proton of one residue and the amide nitrogen of the preceding and succeeding residues or the amide proton of one residue and the amide proton of the preceding and succeeding residues, respectively. These experiments, which we term 3D-HN(CA)NNH and 3D-H(NCA)NNH, utilize an optimized magnetization transfer via the ²J_NC coupling to establish the sequential assignment of backbone NH and ¹⁵N resonances. In contrast to NH-NH connectivities observable in homonuclear NOESY spectra, the assignments from the 3D-H(NCA)NNH experiment are conformation independent to a first-order approximation. Thus the assignments obtained from these experiments can be used as either confirmation of assignments obtained from a conventional homonuclear approach or as an initial step in the analysis of backbone resonances according to Ikura et al. (1990) [Biochemistry, 29, 4659–4667]. Both techniques were applied to uniformly ¹⁵N- and ¹³C-labelled ribonuclease T1.     

Automated classification of RNA 3D motifs and the RNA 3D Motif Atlas

The analysis of atomic-resolution RNA three-dimensional (3D) structures reveals that many internal and hairpin loops are modular, recurrent, and structured by conserved non-Watson–Crick base pairs. Structurally similar loops define RNA 3D motifs that are conserved in homologous RNA molecules, but can also occur at nonhomologous sites in diverse RNAs, and which often vary in sequence. To further our understanding of RNA motif structure and sequence variability and to provide a useful resource for structure modeling and prediction, we present a new method for automated classification of internal and hairpin loop RNA 3D motifs and a new online database called the RNA 3D Motif Atlas. To classify the motif instances, a representative set of internal and hairpin loops is automatically extracted from a nonredundant list of RNA-containing PDB files. Their structures are compared geometrically, all-against-all, using the FR3D program suite. The loops are clustered into motif groups, taking into account geometric similarity and structural annotations and making allowance for a variable number of bulged bases. The automated procedure that we have implemented identifies all hairpin and internal loop motifs previously described in the literature. All motif instances and motif groups are assigned unique and stable identifiers and are made available in the RNA 3D Motif Atlas (http://rna.bgsu.edu/motifs), which is automatically updated every four weeks. The RNA 3D Motif Atlas provides an interactive user interface for exploring motif diversity and tools for programmatic data access.