Residue-specific assignments of resonances in the 1H nuclear magnetic resonance spectrum of ribosomal protein E-L30 by systematic application of two-dimensional Fourier transform nuclear magnetic resonance methods

A two-dimensional Fourier transform nuclear magnetic resonance study of the ribosomal protein E-L30 is reported. Five two-dimensional techniques, namely: nuclear magnetic resonance J-resolved spectroscopy, correlated spectroscopy, double quantum spectroscopy, relayed coherence transfer and nuclear Overhauser enhancement spectroscopy were used. Qualitative inspection of the spectra obtained by these techniques provided evidence that the E-L30 molecule has a well-defined structure in solution. This analysis indicated that, despite the fact that the protein is stable only at moderate temperatures and neutral pH, a structural analysis of the molecule would be feasible. A detailed analysis of the spectra permitted unambiguous discrimination between the spin systems of different amino acids, resulting in residue-specific resonance assignments. We were able to assign all resonances of all six threonine, four valine, five alanine, two histidine, two serine, one phenylalanine, one asparagine and one aspartic acid residue of E-L30. Complete resonance assignment was obtained for two glycine residues. Partial assignments became available for all six isoleucine, three glycine and one glutamine residue. These results form a sound basis for the structure determination of the protein described in the accompanying paper.     

Specific assignment of resonances in the 1H nuclear magnetic resonance spectrum of the polypeptide cardiac stimulant anthopleurin-A

The specific assignment of resonances in the 300-MHz 1H nuclear magnetic resonance (NMR) spectrum of anthopleurin-A, a polypeptide cardiac stimulant from the sea anemone Anthopleura xanthogrammica, is described. Assignments have been made using two-dimensional NMR techniques, in particular the method of sequential assignments, where through-bond and through-space connectivities to the peptide backbone NH resonances are used to identify the spin systems of residues adjacent in the amino acid sequence. Complete assignments have been made of the resonances from 33 residues out of a total of 49, and partial assignments of a further 3. The resonances from several of the remaining residues have been identified but not yet specifically assigned. A complicating factor in making these assignments is the conformational heterogeneity exhibited by anthopleurin-A in solution. The resonances from a number of amino acid residues in the minor conformer have also been assigned. These assignments contribute towards identification of the origin of this heterogeneity, and permit some preliminary conclusions to be drawn regarding the secondary structure of the polypeptide.     

1H NMR studies of porcine calbindin D9k in solution: sequential resonance assignment, secondary structure, and global fold

The 1H nuclear magnetic resonance (NMR) spectrum of Ca2+-saturated porcine calbindin D9k (78 amino acids, Mr 8800) has been assigned. Greater than 98% of the 1H resonances, including spin systems for each amino acid residue, have been identified by using an approach that integrates data from a wide range of two-dimensional scalar correlated NMR experiments [Chazin, Rance, & Wright (1988) J. Mol. Biol. 202, 603-626]. Due to the limited quantity of sample and conformational heterogeneity of the protein, two-dimensional nuclear Overhauser effect (NOE) experiments also played an essential role in the identification of spin systems. On the basis of the pattern of scalar connectivities, 43 of the 78 spin systems could be directly assigned to the appropriate residue type. This provided an ample basis for obtaining the sequence-specific resonance assignments. The elements of secondary structure are identified from sequential and medium-range NOEs, values of 3JNH alpha, and the location of slowly exchanging backbone amide protons. Four well-defined helices and a mini beta-sheet between the two calcium binding loops are present in solution. These elements of secondary structure and a few key long-range NOEs provided sufficient information to define the global fold of the protein in solution. Generally good agreement is found between the crystal structure of the minor A form of bovine calbindin D9k and the solution structure of intact porcine calbindin D9k. The only significant difference is a short one-turn helix in the loop between helices II and III in the bovine crystal structure, which is clearly absent in the porcine solution structure.     

Sequence-specific 1H NMR assignments and secondary structure in the sea anemone polypeptide Stichodactyla helianthus neurotoxin I

Sequence-specific assignments are reported for the 500-MHz 1H nuclear magnetic resonance (NMR) spectrum of the 48-residue polypeptide neurotoxin I from the sea anemone Stichodactyla helianthus (Sh I). Spin systems were first identified by using two-dimensional relayed or multiple quantum filtered correlation spectroscopy, double quantum spectroscopy, and spin lock experiments. Specific resonance assignments were then obtained from nuclear Overhauser enhancement (NOE) connectivities between protons from residues adjacent in the amino acid sequence. Of a total of 265 potentially observable resonances, 248 (i.e., 94%) were assigned, arising from 39 completely and 9 partially assigned amino acid spin systems. The secondary structure of Sh I was defined on the basis of the pattern of sequential NOE connectivities, NOEs between protons on separate strands of the polypeptide backbone, and backbone amide exchange rates. Sh I contains a four-stranded antiparallel beta-sheet encompassing residues 1-5, 16-24, 30-33, and 40-46, with a beta-bulge at residues 17 and 18 and a reverse turn, probably a type II beta-turn, involving residues 27-30. No evidence of alpha-helical structure was found.     

Individual assignments of amide proton resonances in the proton NMR spectrum of the basic pancreatic trypsin inhibitor.

Studies of proton-proton nuclear Overhauser effects were used to obtain individual assignments of 17 amide proton resonances in the 360 MHz proton nuclear magnetic resonance spectrum of the basic pancreatic trypsin inhibitor. First, optimizing the conditions for obtaining selective nuclear Overhauser effects in the presence of spin diffusion in macromolecules is discussed. Truncated driven nuclear Overhauser experiments were used to assing the amide proton resonances of the beta-sheet in the inhibitor. It is suggested that these techniques could serve quite generally to obtain individual resonance assignments in beta-sheet secondary structures of proteins. Combination of nuclear Overhauser studies with spin decoupling further resulted in individual assignments of the gamma-methyl resonances of the two isoleucines and numerous Calpha and Cbeta protons.     

Two-dimensional 1H NMR study of human ubiquitin: a main chain directed assignment and structure analysis

The 1H resonances of human ubiquitin were studied by two-dimensional nuclear magnetic resonance techniques. A recently introduced assignment algorithm termed the main chain directed (MCD) assignment [Englander, S. W., & Wand, A. J. (1987) Biochemistry 26, 5953-5958] was applied. This approach relies on an ordered series of searches for prescribed patterns of connectivities in two-dimensional J-correlated and nuclear Overhauser effect spectra and centers on the dipolar interactions involving main-chain amide NH, alpha-CH, and beta-CH. Unlike the sequential assignment procedure, the MCD approach does not rest upon definition of side-chain J-coupled networks and is generally not sequential with the primary sequence of the protein. The various MCD patterns and the general algorithm are reiterated and applied to the analysis of human ubiquitin. With this algorithm, the vast majority of amino acid residue amide NH-C alpha H-C beta H J-coupled subspin systems could be associated with and aligned within units of secondary structure without any knowledge of the identity of the side chains. This greatly simplified recognition of side-chain spin systems by restricting their identity. Essentially complete resonance assignments are presented. The MCD method is compared with the sequential assignment method in some detail. The MCD method is highly amenable to automation. Human ubiquitin is found, at pH 5.8 and 30 degrees C, to be composed of an extensive beta-sheet structure involving five strands. Three of these strands form an antiparallel set sharing a common strand and have a parallel orientation to two antiparallel strands. Two helical segments were also observed. The largest, spanning 13 residues, shows dipolar interactions consistent with an alpha-helix while the smaller 4-residue helical segment appears, on the basis of observed nuclear Overhauser effects, to be a 3(10) helix. Five classical tight turns could be demonstrated.     

Proton resonance assignments of horse ferrocytochrome c

Two-dimensional nuclear magnetic resonance (NMR) spectroscopy was used to assign the proton resonances of horse ferrocytochrome c. Assignments were based on the main chain directed (MCD) and sequential assignment procedures. The fundamental units of the MCD approach, the main-chain NH-C alpha H-C beta H J-coupled subspin systems of each amino acid residue (NAB sets), were defined by analysis of direct and relayed coherence transfer spectra. Recognition of main-chain NOE connectivity patterns specified in the MCD algorithm then allowed NAB sets to be aligned in their proper juxtaposition within secondary structural units. The units of secondary structure were placed within the polypeptide sequence of identification of a small number of side-chain J-coupled spin systems, found by direct recognition in 2D spectra of some J-coupled spin systems and by pairwise comparisons of the J-correlated spectra of six homologous cytochromes c having a small number of known amino acid differences. The placement of a given segment in this way defines the amino acid identity of all its NAB sets. This foreknowledge allowed the vast majority of the side-chain resonances to be discerned in J-correlated spectra. Extensive confirmation of the assignments derives internally from multiple main-chain NOE connectivities and their consistency following temperature-induced changes of the chemical shifts of NOE-correlated protons. The observed patterns of main-chain NOEs provide some structural information and suggest small but potentially significant differences between the solution structure observed by NMR and that defined earlier in crystallographic studies at 2.8-A resolution.     

PACES: Protein sequential assignment by computer-assisted exhaustive search

A crucial step in determining solution structures of proteins using nuclear magnetic resonance (NMR) spectroscopy is the process of sequential assignment, which correlates backbone resonances to corresponding residues in the primary sequence of a protein, today, typically using data from triple-resonance NMR experiments. Although the development of automated approaches for sequential assignment has greatly facilitated this process, the performance of these programs is usually less satisfactory for large proteins, especially in the cases of missing connectivity or severe chemical shift degeneracy. Here, we report the development of a novel computer-assisted method for sequential assignment, using an algorithm that conducts an exhaustive search of all spin systems both for establishing sequential connectivities and then for assignment. By running the program iteratively with user intervention after each cycle, ambiguities in the assignments can be eliminated efficiently and backbone resonances can be assigned rapidly. The efficiency and robustness of this approach have been tested with 27 proteins of sizes varying from 76 amino acids to 723 amino acids, and with data of varying qualities, using experimental data for three proteins, and published assignments modified with simulated noise for the other 24. The complexity of sequential assignment with regard to the size of the protein, the completeness of NMR data sets, and the uncertainty in resonance positions has been examined.Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1023/A:1023589029301     

Automated sequencing of amino acid spin systems in proteins using multidimensional HCC(CO)NH-TOCSY spectroscopy and constraint propagation methods from artificial intelligence

Summary We have developed an automated approach for determining the sequential order of amino acid spin systems in small proteins. A key step in this procedure is the analysis of multidimensional HCC(CO)NH-TOCSY spectra that provide connections from the aliphatic resonances of residue i to the amide resonances of residue i+1. These data, combined with information about the amino acid spin systems, provide sufficient constraints to assign most proton and nitrogen resonances of small proteins. Constraint propagation methods progressively narrow the set of possible assignments of amino acid spin systems to sequence-specific positions in the process of NMR data analysis. The constraint satisfaction paradigm provides a framework in which the necessary constraint-based reasoning can be expressed, while an object-oriented representation structures and facilitates the extensive list processing and indexing involved in matching. A prototype expert system, AUTOASSIGN, provides correct and nearly complete resonance assignments with one real and 31 simulated 3D NMR data sets for a 72-amino acid domain, derived from the Protein A of Staphylococcus aureus, and with 31 simulated NMR data sets for the 50-amino acid human type- transforming growth factor.     

Complete assignment of aromatic 1H nuclear magnetic resonances of the tyrosine residues of hen lysozyme

The complete assignment of the aromatic proton nuclear magnetic resonances of the three tyrosine residues in hen lysozyme is reported. These assignments were made using double resonance techniques, specific chemical modifications of one residue (Tyr-23), and by interpretation of the effects of paramagnetic lanthanide ions. Some aspects of the behaviour of the tyrosine residues are reported, including pK values, reactivity towards modifying agents and conformational mobility.     

Proton homonuclear correlated spectroscopy as an assignment tool for hyperfine-shifted resonances in medium-sized paramagnetic proteins: cyanide-ligated yeast cytochrome c peroxidase as an example.

Two types of homonuclear proton COSY experiments are shown to be useful in making resonance assignments in cyanide-ligated cytochrome c peroxidase, a 34 kDa paramagnetic heme protein. Both magnitude COSY and phase-sensitive COSY experiments provide spectra useful for making proton assignments to resonances of strongly relaxed hyperfine-shifted protons. This initial investigation demonstrates that COSY experiments combined with NOESY experiments are feasible for hyperfine-shifted protons of paramagnetic proteins larger than metmyoglobins and ferricytochromes c, for which the nuclear spin-lattice relaxation times are in the range 70-300 ms. Taken together, COSY and NOESY experiments, although not yet widely applied to paramagnetic metalloproteins, provide a reliable protocol for accurately assigning hyperfine-shifted resonances that are part of a metalloenzyme's active site. Specific examples of expected proton homonuclear COSY connectivities that were not observed in these experiments are presented, and utilization of COSY with respect to the proton resonance line widths and apparent nuclear relaxation times is discussed. The COSY experiments presented here provide valuable verification of previously proposed hyperfine resonance assignments for cyanide-ligated cytochrome c peroxidase, which were made by using NOESY experiments alone, and in several instances expand these assignments to additional protons in particular amino acid spin systems.     

Assignment of imino proton spectra of yeast phenylalanine transfer ribonucleic acid

Yeast tRNAPhe has been studied by using proton NMR and nuclear Overhauser effect (NOE) with deuterium substitution. Direct NOE evidence is presented for assignment of imino resonances of 23 of 27 base pairs in this tRNA. Other indirect evidence is presented for tentative assignment of four other base pairs. Almost total assignment also has been made of the important noninternally bonded imino protons and tertiary interactions (however, G18-psi 55 remains unassigned). The most surprising result has been identification of GC11 at -13.68 ppm; this is the first time a GC base pair has been identified so far downfield. This peak (GC11) is also identified as the resonance of the unique imino proton that exchanges in a time of more than 1 day, as previously described. These identifications of imino proton resonances made it possible to reinterpret the proton solvent exchange rate data previously published on this tRNA and understand them better. The assignments of resonances should pave the way for more detailed solution study of this tRNA and its interaction with biologically relevant molecules.     

Proton NMR assignments and regular backbone structure of bovine pancreatic ribonuclease A in aqueous solution

Proton NMR assignments have been made for 121 of the 124 residues of bovine pancreatic ribonuclease A (RNase A). During the first stage of assignment, COSY and relayed COSY data were used to identify 40 amino acid spin systems belonging to alanine, valine, threonine, isoleucine, and serine residues. Approximately 60 other NH-alpha CH-beta CH systems were also identified but not assigned to specific amino acid type. NOESY data then were used to connect sequentially neighboring spin systems; approximately 475 of the possible 700 resonances in RNase A were assigned in this way. Our assignments agree with those for 20 residues assigned previously [Hahn, U., & Rüterjans, H. (1985) Eur. J. Biochem. 152, 481-491]. Additional NOESY correlations were used to identify regular backbone structure elements in RNase A, which are very similar to those observed in X-ray crystallographic studies [Wlodawer, A., Borkakoti, N., Moss, D. S., & Howlin, B. (1986) Acta Crystallogr. B42, 379-387].     

Sequence-specific 1H NMR assignments and structural characterization of bovine seminal fluid protein PDC-109 domain b

Sequence-specific resonance assignments for the isolated second or b domain of the bovine seminal fluid protein PDC-109 have been obtained from analysis of two-dimensional 1H NMR experiments recorded at 500 MHz. These assignments include the identification of all aromatic and most aliphatic amino acid resonances. Stereospecific assignment of resonances stemming from the Val2 CH3 gamma,gamma' groups and from seven CH beta,beta' geminal pairs has been accomplished by analysis of 3J alpha beta coupling constants in conjunction with patterns of cross-peak intensities observed in two-dimensional nuclear Overhauser effect (NOESY) spectra. Analysis of NOESY and 3J alpha NH data reveals a small antiparallel beta-sheet involving stretches containing residues 25-28 and 39-42, a cis-proline residue (Pro4), antiparallel strands consisting of residues 1-3, 5-7, and 10-13, and an aromatic cluster composed of Tyr7, Trp26, and Tyr33. The results of distance geometry and restrained molecular dynamics calculations indicate that the global fold of the PDC-109 b domain, a type II module related to those found in fibronectin, is somewhat different from that predicted by modeling the structure on the basis of homology between type II and kringle units. A shallow depression in the molecular surface which presents a solvent-exposed hydrophobic area--a potential ligand-binding site-is identified in the NMR-based models.     

Two-dimensional 1H nuclear magnetic resonance studies on the gene V-encoded single-stranded DNA-binding protein of the filamentous bacteriophage IKe. II. Characterization of the DNA-binding wing with the aid of spin-labelled oligonucleotides

The DNA-binding domain of the single-stranded DNA-binding protein IKe GVP was studied by means of 1H nuclear magnetic resonance, through use of oligonucleotides of two and three adenyl residues in length, that were spin-labelled at their 3' and/or 5' termini. These spin-labelled ligands were found to cause line broadening of specific protein resonances when bound to the protein, although they were present in small quantities, i.e. of the order of 0.04 molar equivalent and less. The line broadening of protein resonances was made manifest by means of difference one and two-dimensional spectroscopy. Difference one-dimensional experiments revealed line broadening of the same protein resonances upon binding of either 3' or 5' spin-labelled oligonucleotides. Evidence in favour of the existence of a fixed 5' to 3' orientation in the binding of oligonucleotides to the protein surface was therefore not obtained from the spin-labelled oligonucleotide binding studies. Residue-specific assignments of broadened resonances could not, or could only sparsely, be derived from the difference one-dimensional spectra, because of the tremendous overlap in the aliphatic region of the spectrum. In contrast, such assignments were easily obtained from the difference two-dimensional spectra, which were recorded by means of both total correlated spectroscopy and nuclear Overhauser effect spectroscopy. Difference signals were detected for 15 spin systems; ten out of these were assigned to the residues I29, Y27, S20, G18, R16, T28, K22, Q21, V19 and S17 in the amino acid sequence of IKe GVP; the other five spin systems could be assigned to a phenylalanyl residue, an arginyl or lysyl residue, an aspartic acid or asparagyl residue, a glycyl residue and a glutamic acid or glutamyl residue. From the evaluation of the relative difference signals, it was concluded that the direct surroundings of the spin-label group of the labelled oligonucleotide in the bound state is composed of the first five residues in the former group of residues and the five residues in the latter group.(ABSTRACT TRUNCATED AT 400 WORDS)     

Application of 13C nuclear magnetic resonance spectroscopy to molecular structural analyses of antibody molecules

A 13C nuclear magnetic resonance study of a mouse anti-dansyl monoclonal antibody is reported. The antibody molecule was specifically labeled with [1-13C]methionine by growing hybridoma cells in serum-free medium. It was possible to observe all the carbonyl carbon resonances of the antibody. Fab and Fc fragments have been obtained from the antibody and used successfully for the assignment of each of the carbonyl resonances to either the Fab or Fc region. It has been shown that the spectrum of the intact antibody is simply those of Fab and Fc superimposed. It has also been shown that site specific assignments of carbonyl resonances can be made by means of a double labeling technique developed by Kainosho and coworkers.     

Proton nuclear magnetic resonance study of the B9(Asp) mutant of human insulin. Sequential assignment and secondary structure

The sequence-specific 1H nuclear magnetic resonance (n.m.r.) assignment of 49 of the 51 amino acid residues of human B9(Asp) insulin in water at low pH is reported. Spin systems were identified using a series of two-dimensional n.m.r. techniques. For the majority of the amino acid residues with unique spin systems, particularly Ala, Thr, Val, Leu, Ile and Lys, the complete spin systems were identified. Sequence-specific assignments were obtained from sequential nuclear Overhauser enhancement (NOE) connectivities. The results indicate that the solution structure of the mutant closely resembles the crystal structure of native insulin. Thus, the NOE data reveal three helical domains all consistent with the secondary structure of the native human 2Zn insulin in the crystal phase. Numerous slowly exchanging amide protons support these structural elements, and indicate a relatively stable structure of the protein. A corresponding resemblance of the tertiary structures in the two phases is also suggested by slowly exchanging amide protons, and by the extreme chemical shift values observed for the beta-protons of B15(Leu) that agree with a close contact between this residue and the aromatic rings of B24(Phe) and B26(Tyr), as found in the crystal structure of the 2Zn insulin. Finally, there are clear indications that the B9(Asp) insulin mutant exists primarily as a dimer under the given conditions.     

The sequence-specific assignment of the 1H-NMR spectrum of an enzyme, horse-muscle acylphosphatase

A complete range of two-dimensional NMR experiments was used for the assignment of the 1H-NMR spectrum of horse muscle acylphosphatase. Firstly the spin systems of some easily identifiable amino acid side chains were assigned. These side chains involved all the aromatic residues and all the leucine, valine, isoleucine, threonine, alanine, proline as well as some of the glycine residues. Analysis of nuclear Overhauser enhancement spectra in our previous work had identified the sequential and long-range patterns characteristics for secondary structure elements. This result had also provided the identification of the main-chain alpha and amide proton resonances. Several of the completely assigned spin systems were then identified as being part of the secondary structure units which led, after analysis of the primary amino acid sequence, to unambiguous sequence-specific assignments. The identification and assignment of the remaining side-chain resonances was then completed and are reported here. These results provide a complete data base for the three-dimensional structure determination of this enzyme in solution.     

Sequential 1H-NMR assignments and secondary structure of the sea anemone polypeptide anthopleurin-A

The sequence-specific assignment of resonances in the 500-MHz 1H-NMR spectrum of a cardioactive sea anemone polypeptide, anthopleurin-A, is described. The assignment procedure involved analysis of two-dimensional phase-sensitive multiple-quantum-filtered, double-quantum, homonuclear Hartmann-Hahn and nuclear Overhauser effect spectra. Using sequential information, specific assignments have been made for resonances arising from all 49 amino acid residues. Resonances arising from a number of residues in a minor conformer present in solution are also assigned. These results greatly extend previous resonance assignments made from spectra acquired at 300 MHz [Gooley, P. R. and Norton, R. S. (1985) Eur. J. Biochem. 153, 529-539] and provide the basis for a more accurate definition of the conformation of anthopleurin-A in aqueous solution. The secondary structure includes a four-stranded antiparallel beta-sheet encompassing residues 2-4, 21-23, 34-36 and 45-49, and possibly a beta-bulge located at Ser-19 and Gly-20. A type II beta-turn is formed by residues 30-33. These structural elements also occur within other related sea anemone polypeptides, but the conformation of the small loop region containing Pro-41 appears to be unique to anthopleurin-A.     

1H NMR resonance assignments, secondary structure, and global fold of Apo bovine calbindin D9k

The solution structure and dynamics of apo bovine calbindin D9k have been studied by a wide range of two-dimensional 1H nuclear magnetic resonance experiments. Due to the presence of conformational heterogeneity in the wild-type protein, the sequential resonance assignment was carried out on a Pro43----Gly mutant. By use of a combination of scalar correlation experiments acquired from H2O solution, 61 of the 76 1H spin systems could be assigned to particular amino acid types. The remaining resonances were assigned by a parallel series of experiments acquired from 2H2O solution. These spin system assignments provided a basis for complete sequential resonance assignments from interresidue backbone nuclear Overhauser effects (NOEs). Elements of secondary structure were identified from sequential and medium-range NOEs, backbone spin-spin coupling constants, and slowly exchanging amide protons. Four sections of helix are delineated, together with a short antiparallel beta-sheet interaction between the peptide loops involved in Ca2+ binding. The global fold is provided by combining these elements of secondary structure with a subset of the long-range, interhelix NOEs. Comparison with similar studies on the Ca2(+)-saturated protein indicates that at this crude level the structures are very similar. However, removal of the Ca2+ does dramatically affect the dynamics of the protein, as judged by amide proton exchange rates and aromatic ring rotation. This is particularly evident in the increased flexibility of the residues in the hydrophobic core.