Triple-resonance Experiments Research Articles

Multiplicity-Selective Coherence Transfer Steps for the Design of Amino Acid-Selective Experiments—A Triple-Resonance Experiment Selective for Asn and Gln

A multiplicity-selective coherence transfer step is discussed, that can replace the normal INEPT transfer in triple-resonance experiments. Depending on the pulse sequence in which they are implemented, amino acid-selective experiments will be created. Two experiments selective for Asn and Gln are proposed.

1H, 15N, 13C, and 13CO Assignments and Secondary Structure Determinationof Basic Fibroblast Growth Factor using 3D Heteronuclear NMR Spectroscopy

Summary The assignments of the ~H, 15N, 13CO and ~3C resonances of recombinant human basic fibroblast growth factor (FGF-2), a protein comprising 154 residues and with a molecular mass of 17.2 kDa, is presented based on a series of three-dimensional triple-resonance heteronuclear NMR experiments. These studies employ uniformly labeled ~SN- and ~SN-/13C-labeled FGF-2 with an isotope incorporation > 95% for the protein expressed in E. coli. The sequence-specific backbone assignments were based primarily on the interresidue correlation of C ~, C ~ and H a to the backbone amide ~H and ~SN of the next residue in the CBCA(CO)NH and HBHA(CO)NH experiments and the intraresidue correlation of C ~, C ~ and H ~ to the backbone amide ~H and ~SN in the CBCANH and HNHA experiments. In addition, C a and C ~ chemical shift assignments were used to determine amino acid types. Sequential assignments were verified from carbonyl correlations observed in the HNCO and HCACO experiments and C ~ correlations from the HNCA experiment. Aliphatic side-chain spin systems were assigned primarily from H(CCO)NH and C(CO)NH experiments that correlate all the atiphatic ~H and ~3C resonances of a given residue with the amide resonance of the next residue. Additional side-chain assignments were made from HCCH-COSY and HCCH-TOCSY experiments. The secondary structure of FGF-2 is based on NOE data involving the NH, H ~ and H ~ protons as well as 3JHNHC~ coupling constants, amide exchange and ~3C~ and 13C1~ secondary chemical shifts. It is shown that FGF-2 consists of 11 well-defined antiparallel 13-sheets (residues 30-34, 39-44, 48-53, 62-67, 71-76, 81-85, 91-94, 103-108, 113-118, 123-125 and 148-152) and a helix-like structure (residues 131-136), which are connected primarily by tight turns. This structure differs from the refined X-ray crystal structures of FGF-2, where residues 131-136 were defined as 13-strand XI. The discovery of the helix-like region in the primary heparin-binding site (residues 128-138) instead of the 13-strand conformation described in the X-ray structures may have important implications in understanding the nature of heparin-FGF-2 interactions. In addition, two distinct conformations exist in solution for the N-terminal residues 9-28. This is consistent with the Xray structures of FGF-2, where the first 17-19 residues were ill defined.

Triple-resonance method for the detection of hyperfine transitions in heavy-alkali metals

The triple-resonance method for the detection of hyperfine transitions in heavy-alkali metals is studied theoretically. The evolution equations of the reduced fictitious tensorial components of the dressed-atom density matrix in an extended fictitious formalism are determined and solved for the stationary state. Illustrative numerical examples of dressed-caesium are included. Previously unexplained triple-resonance experiments on rubidium and caesium are interpreted in detail.

Evidence for oxidation-state-dependent conformational changes in human ferredoxin from multinuclear, multidimensional NMR spectroscopy.

Human ferredoxin belongs to the vertebrate ferredoxin family which includes bovine adrenodoxin. It is a small (13.8 kDa) acidic protein with a [2Fe-2S] cluster. It functions as an electron shuttle in the cholesterol side-chain cleavage reaction which is the first step of steroid hormone biosynthesis. The protein studied here was produced in Escherichia coli and doubly labeled with 13C and 15N. The diamagnetic 15N, 13C', 13C alpha, 13C beta, 1H alpha, and 1HN resonances from about 70% of the 124 amino acid residues for oxidized human ferredoxin and 80% of those for the reduced protein have been assigned primarily on the basis of results from three-dimensional, triple-resonance experiments. Secondary structure features for human ferredoxin in its oxidized and reduced states have been identified from a combination of chemical shift index and NOE data. Comparison of NMR results from the protein in its oxidized and reduced states indicates that structural changes accompany the change in the oxidation state of the [2Fe-2S] cluster. Major differences are localized at two regions: residues 29-31 and residues 109-124; the latter stretch forms the C-terminal region of the protein. The possible functional significance of these oxidation-state-dependent structural changes is discussed.

Solution structure of the C-terminal SH2 domain of the p85α regulatory subunit of phosphoinositide 3-kinase

Heterodimeric class IA phosphoinositide 3-kinase (PI 3-kinase) plays a crucial role in a variety of cellular signalling events downstream of a number of cell-surface receptor tyrosine kinases. Activation of the enzyme is effected in part by the binding of two Src homology-2 domains (SH2) of the 85 kDa regulatory subunit to specific phosphotyrosine-containing peptide motifs within activated cytoplasmic receptor domains. The solution structure of the uncomplexed C-terminal SH2 (C-SH2) domain of the p85α subunit of PI 3-kinase has been determined by means of multinuclear, double and triple-resonance NMR experiments and restrained molecular-dynamics simulated-annealing calculations. The solution structure clearly indicates that the uncomplexed C-SH2 domain conforms to the consensus polypeptide fold exhibited by other SH2 domains, with an additional short helical element at the N terminus. In particular, the C-SH2 structure is very similar to both the p85α N-terminal SH2 domain (N-SH2) and the Src SH2 domain with a root mean square difference (rmsd) for 44 Cα atoms of 1.09 and 0.89 Å, respectively. The canonical BC, EF and BG loops are less well-defined by the experimental restraints and show greater variability in the ensemble of C-SH2 conformers. The lower level of definition in these regions may reflect the presence of conformational disorder, an interpretation supported by the absence or broadening of backbone and side-chain NMR resonances for some of these residues. NMR experiments were performed, where C-SH2 was titrated with phosphotyrosine-containing peptides corresponding to p85α recognition sites in the cytoplasmic domain of the platelet-derived growth-factor receptor. The ligand-induced chemical-shift perturbations indicate the amino-acid residues in C-SH2 involved in peptide recognition follow the pattern predicted from homologous complexes. A series of C-SH2 mutants was generated and tested for phosphotyrosine peptide binding by surface plasmon resonance. Mutation of the invariant Arg36 (βB5) to Met completely abolishes phosphopeptide binding. Mutation of each of Ser38, Ser39 or Lys40 in the BC loop to Ala reduces the affinity of C-SH2 for a cognate phosphopeptide, as does mutation of His93 (BG5) to Asn. These effects are consistent with the involvement of the BC loop and BG loops regions in ligation of phosphopeptide ligands. Mutation of Cys57 (βD5) in C-SH2 to Ile, the corresponding residue type in the p85α N-SH2 domain, results in a change in peptide binding selectivity of C-SH2 towards that demonstrated by p85α N-SH2. This pattern of p85α phosphopeptide binding specificity is interpreted in terms of a model of the p85α/PDGF-receptor interaction.

Sequential resonance assignment of medium-sized 15 N/ 13 C-labeled proteins with projected 4D triple resonance NMR experiments

We recently introduced a new line of reduced-dimensionality experiments making constructive use of axial peak magnetization, which has so far been suppressed as an undesirable artifact in multidimensional NMR spectra [Szyperski, T., Braun, D., Banecki, B. and Wuthrich, K. (1996) J. Am. Chem. Soc., 118, 8146–8147]. The peaks arising from the axial magnetization are located at the center of the doublets resulting from projection. Here we describe the use of such projected four-dimensional (4D) triple resonance experiments for the efficient sequential resonance assignment of 15N/13C-labeled proteins. A 3D \(\underline {\rm{H}}\)α/β\(\underline {\rm{C}}\)α/β(CO)NHN experiment is recorded either in conjunction with 3D HNN or with the newly presented 3D HNN\({\rm{CAHA}}\) scheme. The first combination yields sequential assignments based on the measurement of13 Cα chemical shifts and provides a complete 1H, 13C and 15N resonance assignment of polypeptide backbone and CHnβ moieties. When employing the second combination, 13C=O chemical shifts are not measured, but the sequential assignment relies on both 13Cα and1 Hα chemical shifts. The assignment is performed in a semi-automatic fashion using the program XEASY in conjunction with the newly implemented program SPSCAN. This program package offers routines for the facile mutual interconversion of single-quantum and zero/double-quantum frequencies detected in conventional and reduced-dimensionality spectra, respectively. In particular, SPSCAN comprises a peak picking routine tailored to cope with the distinct peak patterns of projected NMR experiments performed with simultaneous acquisition of central peaks. Data were acquired at 13 °C for the N-terminal 63-residue polypeptide fragment of the 434 repressor. Analysis of these spectra, which are representative for proteins of about 15 kDa when working at commonly used temperatures around 30 °C , demonstrates the efficiency of our approach for the assignment of medium-sized15 N/13C doubly labeled proteins.

Assignment of backbone NMR resonances and secondary structural elements of a reduced monomeric mutant of copper/zinc superoxide dismutase

An extensive series of three-dimensional, triple resonance experiments were performed on a fully labeled 13C, 15N monomeric form of human copper/zinc superoxide dismutase which contains 153 amino acids. The present system, in addition to the mutations at the subunit–subunit interface (Phe50→Glu, Gly51→Glu) which lead to the monomeric form, carries the mutation of the Glu133 to Gln, a residue at the active channel entrance. Firm assignment was found for 97% of the protons, 99% of the 13Cα, 91% of the 15N, 98% of 13C(O) and 90% of the 13Cβ backbone resonances. Analysis of the chemical shift values of 13Cα, Hα, 13Cβ and 13CO, of 3JHNHα coupling constants, of NOEs between backbone protons and of the H–D exchange behavior of amide protons permits the unequivocal detection of elements of secondary structure. The secondary structure of the present monomeric form is very similar to that of the WT enzyme, although the enzymatic activity is 20% of that of the WT protein. © 1997 John Wiley & Sons, Ltd.

Heteronuclear NMR Studies of the Combined Src Homology Domains 2 and 3 of pp60 c-Src: Effects of Phosphopeptide Binding

The results of heteronuclear NMR studies on the combined Src homology domains 2 and 3 (SH3-SH2) of pp60 c-Src are presented. Resonance assignments were obtained using heteronuclear triple-resonance experiments in conjunction with 15N-separated nuclear Overhauser effect spectroscopy (NOESY) data. A modified three-dimensional 13CO-15N-1H spectral correlation experiment [(HACA)CO(CA)-NH] with improved sensitivity is presented that provided additional sequential information and resolved several ambiguities. Chemical shifts and sequential- and medium-range NOE cross peaks indicate that the structures of both the SH3 and SH2 portions of the polypeptide are very similar to those of the isolated SH3 and SH2 domains. Binding of a high-affinity phosphopeptide, EPQpYEEIPIYL, induces large chemical shift changes at several locations in the SH2 domain. Comparison with known results for peptide binding to SH2 domains shows that the residues displaying the largest effects are all involved in peptide binding or undergo significant conformational changes upon binding. However, subtle changes of both 1H and 15N chemical shifts are observed for residues within the SH3 domain and the connecting linker region, indicating possible cross-domain communication.

Sensitivity Enhancement of Triple-Resonance Protein NMR Spectra by Proton Evolution of Multiple-Quantum Coherences Using a Simultaneous 1H and 13C Constant-Time Evolution Period

Short transverse relaxation times of Cα and Hα single-quantum states in proteins reduce signal-to-noise ratios of heteronuclear correlation experiments involving transfers of Cα and Hα coherences. To overcome this “short transverse relaxation problem”, we have developed a simultaneous 1H and 13C constant-time (sim-CT) heteronuclear multiple-quantum coherence (HMQC) scheme. New features in this design include: (i) utilization of heteronuclear multiple-quantum coherences for better transverse relaxation properties, (ii) concatenation of proton evolution into the simultaneous 1H and 13C constant-time period to eliminate separate time periods for proton evolution, and (iii) use of simultaneous 1H and 13C constant-time to remove resonance splitting due to multiple two- and three-bond homo- and heteronuclear scalar couplings. This general approach for sensitivity enhancement is demonstrated for the HA(CA)(CO)NH triple-resonance experiment. Results on proteins show that, compared with the heteronuclear single-q...

1H, 13C, and 15N backbone assignment and secondary structure of the receptor-binding domain of vascular endothelial growth factor.

Nearly complete sequence-specific 1H, 13C, and 15N resonance assignments are reported for the backbone atoms of the receptor-binding domain of vascular endothelial growth factor (VEGF), a 23-kDa homodimeric protein that is a major regulator of both normal and pathological angiogenesis. The assignment strategy relied on the use of seven 3D triple-resonance experiments [HN(CO)CA, HNCA, HNCO, (HCA)CONH, HN(COCA)HA, HN(CA)HA, and CBCA-(CO)NH] and a 3D 15N-TOCSY-HSQC experiment recorded on a 0.5 mM (12 mg/mL) sample at 500 MHz, pH 7.0, 45 degrees C. Under these conditions, 15N relaxation data show that the protein has a rotational correlation time of 15.0 ns. Despite this unusually long correlation time, assignments were obtained for 94 of the 99 residues; 8 residues lack amide 1H and 15N assignments, presumably due to rapid exchange of the amide 1H with solvent under the experimental conditions used. The secondary structure of the protein was deduced from the chemical shift indices of the 1H alpha, 13C alpha, 13C beta, and 13CO nuclei, and from analysis of backbone NOEs observed in a 3D 15N-NOESY-HSQC spectrum. Two helices and a significant amount of beta-sheet structure were identified, in general agreement with the secondary structure found in a recently determined crystal structure of a similar VEGF construct [Muller YA et al., 1997, Proc Natl Acad Sci USA 94:7192-7197].

Studies on the NusB protein of Escherichia coli--expression and determination of secondary-structure elements by multinuclear NMR spectroscopy.

The product of the nusB gene of Escherichia coli modulates the efficiency of transcription termination at nut (N utilization) sites of various bacterial and bacteriophage lambda genes. Similar control mechanisms operate in eukaryotic viruses (e.g. human immunodeficiency virus). A recombinant strain of E. coli producing relatively large amounts of NusB protein (about 10% of cell protein) was constructed. The protein could be purified with high yield by anion-exchange chromatography followed by gel-permeation chromatography. The protein is a monomer of 15.6 kDa as shown by analytical ultracentrifugation. Structural studies were performed using protein samples labelled with 15N, 13C and 2H in various combinations. Heteronuclear three-dimensional triple-resonance NMR experiments combined with a semi-automatic assignment procedure yielded the sequential assignment of the 1H, 13C and 15N backbone resonances. Based on experimentally derived scalar couplings, chemical-shift values, amide-exchange data, and a semiquantitative interpretation of NOE data, the secondary structure of NusB has classified as alpha helical, comprising seven alpha helices.

Determination of the secondary structure and global topology of the 44 kda ectodomain of gp41 of the simian immunodeficiency virus by multidimensional nuclear magnetic resonance spectroscopy

The gp41 protein of the human (HIV) and simian (SIV) immunodeficiency viruses is part of the envelope glycoprotein complex gp41/gp120 which plays an essential role in viral infection. We present a multidimensional NMR study on the trimeric 44 kDa soluble ectodomain of SIV gp41 (e-gp41), comprising residues 27 to 149. Despite the large molecular weight and very limited spectral dispersion, complete backbone 1H, 13C, 13CO and 15N assignments have been made using a combination of triple resonance experiments on uniformly 13C/ 15N and 2H/ 13C/ 15N-labeled samples. The secondary structure of SIV e-gp41, derived on the basis of 13C chemical shifts, NH exchange rates, medium range nuclear Overhauser enhancements (NOE), and 3 J HNα coupling constants, consists of a 49 residue helix at the N terminus (residues 29 to 77) and a 40 residue helix at the C terminus (residues 108 to 147), connected by a 30 residue loop which does not display any of the characteristics of regular secondary structure. The cross-peak intensities of the loop region in scalar correlation experiments suggests that it is more mobile than the core helical regions. The presence, however, of numerous long range NOEs, both intra and inter-subunit, within the loop indicates that it adopts a well-defined structure in which the loops from the three subunits interact with each other. Based on a number of long range intra and inter-subunit NOEs, a topological model is presented for the symmetric SIV e-gp41 trimer in which the N-terminal helices are packed within the protein interior in a parallel trimeric coiled-coil arrangement, while the C-terminal helices are located on the protein exterior, oriented antiparallel to the N-terminal helices.

NMR structural studies of human cystatin C dimers and monomers

Human cystatin C undergoes dimerization before unfolding. Dimerization leads to a complete loss of its activity as a cysteine proteinase inhibitor. A similar process of dimerization has been observed in cells, and may be related to the amyloid formation seen for the L68Q variant of the protein. Dimerization is barrier controlled, and no dimer/monomer interconversion can be observed at physiological conditions. As a consequence, very stable, “trapped” dimers can be easily separated from monomers. A study of the structural aspects of cystatin C dimer formation was undertaken using NMR spectroscopy. The monomer/dimer model was verified by (pulse field gradient NMR) self-diffusion molecular mass measurements. Complete backbone resonance assignments and secondary structure determination were obtained for the monomer using data from triple resonance experiments performed on 13C/ 15N doubly labeled protein. A marked similarity of the cystatin C secondary structure to that of chicken cystatin was observed. Using uniformly and amino-acid-specific 15N-enriched protein, backbone NH signals were assigned for cystatin C in its dimeric state. Comparison of 1H- 15N correlation NMR spectra of the monomer and dimer shows that the three-dimensional structure remains unchanged in the dimer and that only local perturbations occur. These are localized to the amino acid residues comprising the cysteine proteinase binding site. Such a mode of dimerization readily explains the complete loss of the inhibitory activity in the dimer. The NMR results also demonstrate that the dimer is symmetric.

Automated analysis of protein NMR assignments using methods from artificial intelligence

An expert system for determining resonance assignments from NMR spectra of proteins is described. Given the amino acid sequence, a two-dimensional 15N- 1H heteronuclear correlation spectrum and seven to eight three-dimensional triple-resonance NMR spectra for seven proteins, AUTOASSIGN obtained an average of 98% of sequence-specific spin-system assignments with an error rate of less than 0.5%. Execution times on a Sparc 10 workstation varied from 16 seconds for smaller proteins with simple spectra to one to nine minutes for medium size proteins exhibiting numerous extra spin systems attributed to conformational isomerization. AUTOASSIGN combines symbolic constraint satisfaction methods with a domain-specific knowledge base to exploit the logical structure of the sequential assignment problem, the specific features of the various NMR experiments, and the expected chemical shift frequencies of different amino acids. The current implementation specializes in the analysis of data derived from the most sensitive of the currently available triple-resonance experiments. Potential extensions of the system for analysis of additional types of protein NMR data are also discussed.

An Easy Way for Resolution Enhancement in Out-and-Back Triple-Resonance Experiments Applied to the HCACO Sequence

An Easy Way for Resolution Enhancement in Out-and-Back Triple-Resonance Experiments Applied to the HCACO Sequence

Secondary structure of the IIB domain of the Escherichia coli mannose transporter, a new fold in the class of α/β twisted open-sheet structures

The mannose transporter of the Escherichia coli bacterial phosphotransferase system consists of three subunits: IIAB, IIC and IID. IIAB Man transfers phosphoryl groups to the transported substrate via phosphohistidine intermediates. Its IIB domain was overexpressed and isotopically labelled with 13C, 15N and 2H. Heteronuclear 3D triple-resonance NMR experiments combined with a semi-automatic assignment procedure yielded the sequential assignment of the 1H, 13C and 15N backbone resonances. Based on the evaluation of conformationally sensitive parameters, the secondary structure of the IIB Man domain has been determined as an α/β twisted open-sheet structure consisting of a six-stranded parallel β-sheet with the novel strand order 3–2–4–1–5–6, six helices and a short two-stranded antiparallel β-sheet. © 1997 Federation of European Biochemical Societies.

Global folds of highly deuterated, methyl-protonated proteins by multidimensional NMR.

The development of 15N, 13C, 2H multidimensional NMR spectroscopy has facilitated the assignment of backbone and side chain resonances of proteins and protein complexes with molecular masses of over 30 kDa. The success of these methods has been achieved through the production of highly deuterated proteins; replacing carbon-bound protons with deuterons significantly improves the sensitivity of many of the experiments used in chemical shift assignment. Unfortunately, uniform deuteration also radically depletes the number of interproton distance restraints available for structure determination, degrading the quality of the resulting structures. Here we describe an approach for improving the precision and accuracy of global folds determined from highly deuterated proteins through the use of deuterated, selectively methyl-protonated samples. This labeling profile maintains the efficiency of triple-resonance NMR experiments while retaining a sufficient number of protons at locations where they can be used to establish NOE-based contacts between different elements of secondary structure. We evaluate how this deuteration scheme affects the sensitivity and resolution of experiments used to assign 15N, 13C, and 1H chemical shifts and interproton NOEs. This approach is tested experimentally on a 14 kDa SH2/phosphopeptide complex, and a global protein fold is obtained from a set of methyl-methyl, methyl-NH, and NH-NH distance restraints. We demonstrate that the inclusion of methyl-NH and methyl-methyl distance restraints greatly improves the precision and accuracy of structures relative to those generated with only NH-NH distance restraints. Finally, we examine the general applicability of this approach by determining the structures of several proteins with molecular masses of up to 40 kDa from simulated distance and dihedral angle restraint tables.

Application of multiple-quantum line narrowing with simultaneous 1H and 13C constant-time scalar-coupling evolution in PFG-HACANH and PFG-HACA(CO)NH triple-resonance experiments.

Many triple-resonance experiments make use of one-bond heteronuclear scalar couplings toestablish connectivities among backbone and/or side-chain nuclei. In medium-sized(15-30 kDa) proteins, short transverse relaxation times of Calpha single-quantum stateslimit signal-to-noise (S/N) ratios. These relaxation properties can be improved usingheteronuclear multiple-quantum coherences (HMQCs) instead of heteronuclear single-quantumcoherences (HSQCs) in the pulse sequence design. In slowly tumbling macromolecules, theseHMQCs can exhibit significantly better transverse relaxation properties than HSQCs.However, HMQC-type experiments also exhibit resonance splittings due to multiple two- andthree-bond homo- and heteronuclear scalar couplings. We describe here a family of pulsed-field gradient (PFG) HMQC-type triple-resonance experiments using simultaneous 1H and13C constant-time (CT) periods to eliminate the t1 dependence of these scalar couplingeffects. These simultaneous CT PFG-(HA)CANH and PFG-(HA)CA(CO)NH HMQC-typeexperiments exhibit sharper resonance line widths and often have better S/N ratios than thecorresponding HSQC-type experiments. Results on proteins ranging in size from 6 to 30 kDashow average methine CalphaH HMQC:HSQC enhancement factors of 1.10 +/- 0.15, withabout 40% of the cross peaks exhibiting better S/N ratios in the simultaneous CT-HMQCversions compared with the HSQC versions.

1H, 13C, and 15N NMR backbone assignments and chemical-shift-derived secondary structure of glutamine-binding protein of Escherichia coli.

1H, 13C, and 15N NMR assignments of the backbone atoms and beta-carbons have been made for liganded glutamine-binding protein (GlnBP) of Escherichia coli, a monomeric protein with 226 amino acid residues and a molecular weight of 24935 Da. GlnBP is a periplasmic binding protein which plays an essential role in the active transport of L-glutamine through the cytoplasmic membrane. The assignments have been obtained from three-dimensional triple-resonance NMR experiments on a 13C, 15N uniformly labeled sample as well as specifically labeled samples. Results from the 3D triple-resonance experiments, HNCO, HN(CO)CA, HN(COCA)HA, HNCA, HN(CA)HA, HN(CA)CO, and CBCA(CO)NH, are the main sources used to make the resonance assignments. Other 3D experiments, such as HNCACB, COCAH, HCACO, HCACON, and HOHAHA-HMQC, have been used to confirm the resonance assignments and to extend connections where resonance peaks are missing in some of the experiments mentioned above. We have assigned more than 95% of the polypeptide backbone resonances of GlnBP. The result of the standard manual assignment is in agreement with that predicted by an automated probailistic method developed in our laboratory. A solution secondary structure of the GlnBP-Gln complex has been proposed based on chemical shift deviations from random coil values. Eight alpha-helices and 10 beta-strands are derived using the Chemical Shift Index method.

Triple-resonance NOESY-based experiments with improved spectral resolution: applications to structural characterization of unfolded, partially folded and folded proteins.

NMR-based structural studies of macromolecules focus to a large extent on the establishment of interproton distances within the molecule based on the nuclear Overhauser effect (NOE). Despite the improvements in resolution resulting from multidimensional NMR experiments, the detailed characterization of disordered states of proteins or highly overlapped regions of folded molecules using current NMR methods remains challenging. A suite of triple-resonance NOESY-type pulse schemes is presented which require uniform 15N and 13C labeling and make use of the chemical shift dispersion of backbone 15N and 13C' (carbonyl) resonances to increase the spectral resolution. In particular, for the case of partially folded and unfolded proteins, the experiments exploit the fact that the dispersion of 15N and 13C' resonances is comparable to that observed in folded states. Ambiguities that arise in the assignment of NOEs as a result of the severe chemical shift degeneracy in 1H and aliphatic 13C nuclei are resolved, therefore, by recording the chemical shifts of 15N or 13C' either before or after the NOE mixing period. Applications of these methods to the study of the unfolded state of the N-terminal SH3 domain of drk (drkN SH3) and a partially folded large fragment of staphylococcal nuclease (SNase), delta 131 delta, are presented. In addition, an application to folded SNase in complex with the ligands thymidine 3',5'-bisphosphate (pdTp) and Ca2+ is illustrated which allows the assignment of NOEs between degenerate H alpha protons or protons resonating close to water.