Backbone dynamics of the major coat protein of bacteriophage M13 in detergent micelles by 15N nuclear magnetic resonance relaxation measurements using the model-free approach and reduced spectral density mapping.

The backbone dynamics of the major coat protein (gVIIIp) of the filamentous bacteriophage M13, solubilized in detergent micelles, have been studied using 15N nuclear magnetic resonance spectroscopy at three frequencies. Motional parameters and overall and internal correlation times were derived with the model-free approach. It was also checked whether these parameters had to be modified due to anisotropic motion of the protein/micelle complex. Reduced spectral density mapping was used to calculate the spectral densities at J(O), J(omegaN), and [J(omegaH)]. The spectral densities were interpreted by mapping a linear or scaled linear combination of two Lorentzians onto a J(O)-J(omega) plot. The major coat protein of bacteriophage M13 consists of two alpha-helices, one of which is hydrophobic and located within the micelle, while the other is amphipathic and located on the surface of the micelle. Our results indicate that the motion of the hydrophobic helix is restricted such that it corresponds to the overall tumbling of the protein/micelle complex. The interpretation of the relaxation data of the amphipathic helix by means of the model-free approach and the reduced spectral density mapping indicate that in addition to the overall motion all residues in this helix are subject to motion on the fast nanosecond and picosecond time scales. The motions of the vectors in the low nanosecond range are characterized by similar values of the spectral densities and correlation times and represent the motion of the amphipathic helix on and away from the surface of the micelle. The relaxation data of the residues in the hinge region connecting the helices show that there is an abrupt change from highly restricted to less restricted motion. Both the C-terminal and N-terminal residues are very mobile.

Estimating the relative populations of 3(10)-helix and alpha-helix in Ala-rich peptides: a hydrogen exchange and high field NMR study.

Recent experimental and theoretical work suggests that alanine-rich peptides fold as a mixture of 3(10)-helix (i --> i + 3 hydrogen bonding) and alpha-helix (i --> i + 4 hydrogen bonding). In order to assess the relative proportions of the two conformers, NMR studies were performed on the 16 residue sequences: Ac-AAAAKAAAAKAAAAKA-NH2 (3K) and Ac-AMAAKAWAAKAAAARA-NH2 (MW). Hydrogen/deuterium-exchange kinetics measured for the first three amide protons of the 3K peptide indicate that the NH of Ala3 is partially protected from exchange. This result is consistent with the presence of an i --> i + 3 hydrogen bond between the carbonyl group of the acetyl blocking group and the NH group of Ala3. The MW peptide is a modified version of the 3K peptide, designed to increase alphaH signal dispersion. 1H NMR spectra of the MW peptide at 750 MHz reveal a series of intermediate range (NOEs) consistent with a mixture of 3(10)-helix and alpha-helix. The relative intensities of the alphaN(i,i + 3) and alphabeta(i,i + 3) (nuclear Overhauser enhancements) NOEs suggest that 3(10)-helix is present throughout the peptide, but with the greatest contribution at the termini. A model was developed to determine the relative contributions of 3(10)-helix and alpha-helix. Lower bounds for the population of 3(10)-helix are approximately 50% at the termini and 25% in the middle of the peptide. The greatest alpha-helical content is between the middle of the peptide and the N terminus.

Local helix content in an alanine-rich peptide as determined by the complete set of 3JHN alpha coupling constants.

Alanine-rich peptides serve as models for exploring the factors that control helix structure in peptides and proteins. Scalar C alpha H-NH couplings (3JHN alpha) are an extremely useful measure of local helix content; however, the large alanine content in these peptides leads to significant signal overlap in the C alpha H region of 1H 2D NMR spectra. Quantitative determination of all possible 3JHN alpha values is, therefore, very challenging. Szyperski and co-workers [(1992) J. Magn. Reson. 99, 552-560] have recently developed a method for determining 3JHN alpha from NOESY spectra. Because 3JHN alpha may be determined from 2D peaks outside of the C alpha H region, there is a much greater likelihood of identifying resolved resonances and measuring the associated coupling constants. It is demonstrated here that 3JHN alpha can be obtained for every residue in the helical peptide Ac-(AAAAK)3A-NH2. The resulting 3JHN alpha profile clearly identifies a helical structure in the middle of the peptide and further suggests that the respective helix termini unfold via distinct pathways.

Structures of lantibiotics studied by NMR.

During the last decade, Nuclear Magnetic Resonance has played an important role in the unravelling of the primary and tertiary structures of lantibiotics. A short overview of these studies, together with typical spatial structures obtained, is presented.

Backbone dynamics of the 269-residue protease Savinase determined from 15N-NMR relaxation measurements.

Backbone dynamics of Savinase, a subtilisin of 269 residues secreted by Bacillus lentus, have been studied using 15N relaxation measurements derived from proton-detected dimensional 1H-15N-NMR spectroscopy. 15N spin-lattice rate constants (R1), spin-spin relaxation-rate constants(R2), and 1H-15N nuclear Overhauser effects (NOE) were determined for 84% of the backbone amide 15N nuclei. The model-free formalism [Lipari, G. & Szabo, A. (1982) J. Am. Chem. Soc. 104, 4546-4559] was used to derive values for a generalized order parameter, S2, interpretable as a measure of the amplitude of motion on the picosecond-nanosecond timescale, for each N-H bond vector. Additional terms used to fit the data include an effective correlation time for internal motions (taue) and an exchange term (Rex) to account for exchange contributions to R2. The overall rotational correlation time (taum) is 9.59 +/- 0.02 ns; the average order parameter (S2) is 0.90 +/- 0.07, indicative of a rigid structure consistent with Savinase's high degree of secondary structure and compact tertiary fold. Residues S125-S128, located in the substrate-binding region, represent the longest stretch of protein which exhibits disorder on the picosecond-nanosecond timescale. These residues also exhibit significant exchange terms, possibly indicative of motion on the microsecond-millisecond timescale, which could also be influenced by the proximity of the phenyl ring of the substituted aryl boronic acid inhibitor used in this study. S103 and G219 in the substrate-binding region, represent the longest stretch of protein which exhibits disorder on the picosecond-nanosecond timescale. These residues also exhibit significant exchange terms, possibly indicative of motion on the microsecond-millisecond timescale, which could also be influenced by the proximity of the phenyl ring of the substituted aryl boronic acid inhibitor used in this study. S103 and G219 in the substrate-binding region also show flexibility on the picosecond-nanosecond timescale. There is also significant motion in the turn, G258-T260, of a small solvent-exposed loop region which may make the protein vulnerable autolysis at that point. Some residues in both calcium-binding sites and nearby also show mobility.

Three-dimensional structure of the lantibiotic nisin in the presence of membrane-mimetic micelles of dodecylphosphocholine and of sodium dodecylsulphate.

The lantibiotic nisin is a cationic, polycyclic bacteriocin of 34 residues, including several unusual dehydro residues and thioether-bridged lanthionines. The primary target of its antimicrobial action is the cytoplasmic membrane. Therefore the conformation of nisin when bound to membrane-mimicking micelles of zwitterionic dodecylphosphocholine and of anionic sodium dodecylsulphate was determined with high-resolution NMR spectroscopy. Structures were calculated on the basis of NMR-derived constraints with the distance-geometry program DIANA and were further refined by restrained energy minimization using X-PLOR. The conformation of nisin complexed to both types of micelles is the same, irrespective of the different polar head-groups of the detergents. The structure consists of two structured domains: an N-terminal domain (residues 3-19) containing three lanthionine rings, A, B and C; and a C-terminal domain (residues 22-28) containing two intertwined lanthionine rings numbered D and E. These domains are flanked by regions showing structural variability. Both domains are clearly amphipathic, a property characteristic for membrane-interacting polypeptides. The structures of the ring systems are better defined than those of the linear segments. The four-residue rings B, D and E of nisin all show a beta-turn structure, which is closed by the thioether linkage. The backbones of the rings B and D form type 11 beta-turns. Ring E resembles a type I beta-turn. Preceding the intertwined rings D (residues 23-26) and E (25-28) another type-II beta-turn is found formed by the residues 21-24, so that the C-terminal domain consists of three consecutive beta-turns. The structures of nisin in the micellar systems differ significantly from the previously determined (and now partially recalculated) structure in aqueous solution [van de Ven, F. J. M., van den Hooven, H. W., Konings, R. N. H. & Hilbers, C. W. (1991) Eur J. Biochem. 202, 1181-1188] in the first lanthionine ring around dehydroalanine 5.

Determination of the three-dimensional solution structure of scyllatoxin by 1H nuclear magnetic resonance.

The three-dimensional solution structure of Scyllatoxin (leiurotoxin I) a venom peptide from the scorpion Leiurus quinquestriatus hebraeus was determined at 1 A resolution by homonuclear proton n.m.r. methods at 500 MHz. Data analysis and structure calculation followed conventional protocols inherent to DIANA and related programs with two exceptions. First, distance constraints were obtained from two-dimensional nuclear Overhauser spectra by a previously described partial relaxation matrix approach. Second, since the pairing pattern of the six cysteine residues was not established a priori, the unequivocal assignment of the disulfide bridges was achieved exclusively from the n.m.r. data by a statistical analysis of preliminary DIANA structures. In the final calculation we used 227 upper distance constraints, 67 torsional constraints from vicinal coupling constants and ten stereospecific assignments of beta-methylene protons. Scyllatoxin folds into a compact ellipsoidal shape. An alpha-helix (defined with 0.24 A resolution) spanning 2.5 turns from Leu5 till Ser14 is stabilized by Cys8-Cys26 and Cys12-Cys28 disulfide bridges to the carboxy-terminal strand of an anti-parallel beta-sheet. The antiparallel beta-sheet (defined at 0.66 A resolution) extends from Leu18 to Val29 with a tight turn at Gly23-Asp24 and displays a right-handed twist. Scyllatoxin competes with the toxins apamin from Apis mellifera mellifera and P05 from Androctonus mauretanicus mauretanicus for the same or similar high conductance calcium-activated potassium channels. Consideration of presently known biological activities and three-dimensional structures of these toxins suggest a different toxin-receptor interaction of scyllatoxin as compared to apamin and P05.

NMR studies of the major coat protein of bacteriophage M13. Structural information of gVIIIp in dodecylphosphocholine micelles.

The membrane-bound form of the major coat protein (gVIIIp) of bacteriophage M13 has been studied using nuclear magnetic resonance spectroscopy. As membrane mimetics, we used dodecylphosphocholine (DodPCho) detergent micelles to solubilize the protein. We were able to nearly completely assign all resonances of the protein solubilized in DodPCho micelles by using both homonuclear and heteronuclear multidimensional experiments. Based on the patterns of the nuclear Overhauser enhancements and the chemical shifts of the resonances, we deduced the secondary structure of the protein. Additional structural information was obtained from amide proton exchange data and J-coupling constants. The protein consists of two alpha-helices which are connected by a hinge region around residue 21. From spin-label experiments, the location of the protein relative to the DodPCho micelles was determined. One, hydrophobic, helix spans the micelle, and another, amphipathic, helix, is located beneath the surface of the micelle. Comparison of the data of gVIIIp in DodPCho micelles with those of gVIIIp in sodium dodecyl sulfate (SDS) micelles [Van de Ven, F. J. M., van Os, J. W. M., Aelen, J. M. A., Wymenga, S. S., Remerowski, M. L., Konings, R. N. H. & Hilbers, C. W. (1993) Biochemistry 32, 8322-8328; Papavoine, C. H. M., Konings, R. N. H., Hilbers, C. W. & Van de Ven, F. J. M. (1994) Biochemistry 33, 12,990-12,997] reveals that the structures of the protein in the two detergent micelles are very similar. They differ only in the arrangement of the detergent molecules around the protein. For gVIIIp in SDS micelles, we found a micellar structure which is distorted near the C-terminus of the protein; whereas for DodPCho micelles, both distorted and regular elliptical micelles occur. This distortion is probably due to the interaction of the positively charged lysine side chains with the negatively charged head group of the detergent molecules.

Elucidation of the primary structure of the lantibiotic epilancin K7 from Staphylococcus epidermidis K7. Cloning and characterisation of the epilancin-K7-encoding gene and NMR analysis of mature epilancin K7.

Lantibiotics are bacteriocins that contain unusual amino acids such as lanthionines and alpha, beta-didehydro residues generated by posttranslational modification of a ribosomally synthesized precursor protein. The structural gene encoding the novel lantibiotic epilancin K7 from Staphylococcus epidermidis K7 was cloned and its nucleotide sequence was determined. The gene, which was named elkA, codes for a 55-residue preprotein, consisting of an N-terminal 24-residue leader peptide, and a C-terminal 31-residue propeptide which is posttranslationally modified and processed to yield mature epilancin K7. In common with the type-A lantibiotics nisin A and nisin Z, subtilin, epidermin, gallidermin and Pep5, pre-epilancin K7 has a so-called class-Al leader peptide. Downstream and upstream of the elkA gene, the starts of two open-reading-frames, named elkP and elkT, were identified. The elkP and elkT genes presumably encode a leader peptidase and a translocator protein, respectively, which may be involved in the processing and export of epilancin K7. The amino acid sequence of the unmodified pro-epilancin K7, deduced from the elkA gene sequence, is in full agreement with the amino acid sequence of mature epilancin K7, determined previously by means of NMR spectroscopy [van de Kamp, M., Horstink, L. M., van den Hooven, M. W., Konings, R. N. M., Hilbers, C. W., Sahl, H.-G., Metzger, J. W. & van de Ven, F. J. M. (1995) Eur. J. Biochem. 227, 757-771]. The first residue of mature epilancin K7 appears to be modified in a way that has not been described for any other lantibiotic so far. NMR experiments show that the elkA-encoded serine residue at position +1 of pro-epilancin K7 is modified to a 2-hydroxypropionyl residue in the mature protein.

Sequence analysis by NMR spectroscopy of the peptide lantibiotic epilancin K7 from Staphylococcus epidermidis K7.

The amino acid sequence of the novel lantibiotic epilancin K7 from Staphylococcus epidermidis K7 was determined by NMR spectroscopy. NMR spectroscopy was used because sequencing by conventional Edman degradation techniques was prohibited by internal sequence blocks owing to the presence of modified residues. Epilancin K7 consists of 31 residues, including two alpha,beta-didehydroalanine (one-letter code U) and two alpha,beta-didehydrobutyrine (O) residues, one lanthionine (A-S-A), two beta-methyllanthionines (A*-S-A), and six lysines. Epilancin K7 has a molecular mass of 3032 +/- 1.5 Da. The amino acid sequence of epilancin K7 was derived from both through-space dipolar proton-proton interactions and through-bond scalar proton-carbon interactions as detected by two-dimensional 1H-NOESY, 1H-ROESY and three-dimensional 1H-TOCSY-NOESY, and by two-dimensional 1H,13C-heteronuclear multiple-bond correlation spectroscopy, respectively. The sequence is as follows: [sequence: see text] The N-terminal residue X partly resembles an alanine but its exact nature is unclear. The organization of the sulfide-bridge-containing (beta-methyl-)lanthionines was revealed by 1H-NMR and 1H,13C-NMR spectroscopy. Epilancin K7 has a linear structure and a high positive net charge, and therefore is classified as a type-A lantibiotic. NMR analysis of a degraded though still active form of epilancin K7 showed that two N-terminal residues of epilancin K7 were missing, owing to decomposition at the alpha,beta-didehydro alanine at position 3; it was called the epilancin K7-(3-31)-peptide (peptide fragment of epilancin K7 consisting of positions 3-31). The usefulness of three-dimensional 1H-TOCSY-NOESY, and two-dimensional 1H,13C-heteronuclear multiple-bond correlation spectroscopy at natural abundance for the study of (modified) polypeptides is demonstrated.

Location of M13 coat protein in sodium dodecyl sulfate micelles as determined by NMR.

The major coat protein (gVIIIp) of bacteriophage M13 solubilized in sodium dodecyl sulfate (SDS) detergent micelles was used as a model system to study this protein in the lipid-bound form. In order to probe the position of gVIIIp relative to the SDS micelles, stearate was added, spin-labeled at the 5- or 16-position with a doxyl group containing a stable nitroxide radical. The average position of the spin-labels in the micelles was derived from the line broadening of the resonances in the 13C spectrum of SDS. Subsequently, we derived a model of the relative position of gVIIIp in the SDS micelle from the effect of the spin-labels on the gVIIIp resonances, monitored via 1H-15N HSQC and TOCSY experiments. The results are consistent with the structure of gVIIIp having two helical strands. One strand is a long hydrophobic helix that spans the micelle, and the other is a shorter amphipathic helix on the surface of the micelle. These results are in good agreement with the structure of gVIIIp in membranes proposed by McDonnell et al. on the basis of solid state NMR data [McDonnell, P. A., Shon, K., Kim, Y., & Opella, S. J. (1993) J. Mol. Biol. 233, 447-463]. This study indicates that high-resolution NMR on this membrane protein, solubilized in detergent micelles, is a very suitable technique for mimicking these proteins in their natural environment. Furthermore, the data indicate that the structure of the micelle near the C-terminus of the major coat protein is distorted.(ABSTRACT TRUNCATED AT 250 WORDS)

Solution structure of the type 1 blue copper protein amicyanin from Thiobacillus versutus.

A three-dimensional solution structure of amicyanin from Thiobacillus versutus has been determined by distance geometry and restrained molecular dynamics. A total of 984 experimentally derived constraints were used for the final refinement (881 distance constraints and 103 dihedral angle constraints). Stereospecific assignments were made for 17 prochiral beta-methylene protons (33%) and the methyl groups of eight valine residues. Fourteen structures were selected to represent the solution structure. They show an average pairwise backbone root-mean-square deviation of 1.19 A. The overall structure can be described as a beta-sandwich, built up of nine beta-strands. The copper atom is located between three loops on one end of the molecule. Two of these loops contribute the copper ligands. His54 is on the loop between beta-strands 4 and 5. The other three ligands, Cys93, His96 and Met99, are located evenly spaced on the loop between beta-strands 8 and 9. This loop is folded in two consecutive type 1 turns with His96 as the donor and acceptor of the NHi-CO(i-3) hydrogen bonds. The folding is reminiscent of the general cupredoxin fold. Considerably different are the large 21 residue N-terminal extension, that is unique to amicyanin and forms an extra beta-strand (strand 1), and the region between beta-strands 5 and 7. The partly surface-exposed copper ligand His96 is surrounded by a hydrophobic patch consisting of seven residues.

The solution structure of the hairpin formed by d(TCTCTC-TTT-GAGAGA).

The 15-residue oligonucleotide d(TCTCTC-TTT-GAGAGA) forms a hairpin structure with a loop of three thymidine residues at neutral pH or above. The three-dimensional solution structure of this oligonucleotide has been determined by means of two-dimensional nuclear magnetic resonance methods. Interproton distance constraints derived from NOEs, in combination with torsion angle constraints obtained from J-coupling constants were used in the variable target function program DIANA to derive the hairpin structure. It was found that hairpins with two different loop conformations fit the NMR data, i.e. an equilibrium between these two conformational states can only fully explain the NOE data available. In one state, loop residue T7 is turned into the minor groove, while in the second state residue T8 is in the minor groove. In both conformations the phosphate backbone changes its direction by 180 degrees between residues T9 and G10. Concomitantly, torsion angles zeta of T9 and alpha of G10 both adopt a gauche(+) conformation and gamma of residue G10 adopts a trans conformation to induce this complete change in the direction of the backbone.

1H, 13C and 15N NMR backbone assignments and secondary structure of the 269-residue protease subtilisin 309 from Bacillus lentus.

1H, 13C and 15N NMR assignments of the backbone atoms of subtilisin 309, secreted by Bacillus lentus, have been made using heteronuclear 3D NMR techniques. With 269 amino acids, this protein is one of the largest proteins to be sequentially assigned by NMR methods to date. Because of the size of the protein, some useful 3D correlation experiments were too insensitive to be used in the procedure. The HNCO, HN(CO)-CA, HNCA and HCACO experiments are robust enough to provide most of the expected correlations for a protein of this size. It was necessary to use several experiments to unambiguously determine a majority of the alpha-protons. Combined use of HCACO, HN(COCA)HA, HN(CA)HA, 15N TOCSY-HMQC and 15N NOESY-HMQC experiments provided the H alpha chemical shifts. Correlations for glycine protons were absent from most of the spectra. A combination of automated and interactive steps was used in the process, similar to that outlined by Ikura et al. [(1990) J. Am. Chem. Soc., 112, 9020-9022] in the seminal paper on heteronuclear backbone assignment. A major impediment to the linking process was the amount of overlap in the C alpha and H alpha frequencies. Ambiguities resulting from this redundancy were solved primarily by assignment of amino acid type, using C alpha chemical shifts and 'TOCSY ladders'. Ninety-four percent of the backbone resonances are reported for this subtilisin. The secondary structure was analyzed using 3D 15N NOESY-HMQC data and C alpha secondary chemical shifts. Comparison with the X-ray structure [Betzel et al. (1992) J. Mol. Biol., 223, 427-445] shows no major differences.

Assignment of 1H, 15N, and backbone 13C resonances in detergent-solubilized M13 coat protein via multinuclear multidimensional NMR: a model for the coat protein monomer.

The major coat protein (gVIIIp) of bacteriophage M13 complexed with SDS detergent micelles was used as a model system to study the lipid-bound conformation of the protein. Conditions were found that allowed the recording of good quality of NMR spectra. By making extensive use of three-dimensional heteronuclear (13C, 15N) NMR, we obtained a complete set of resonance assignments for 1HN, 1H alpha, 1H beta, 13C alpha, CO, and 15N and partially assigned the rest of the 1H spectrum. Analysis of NOE and chemical shift data reveals that gVIIIp is composed of two alpha-helical domains, one ranging from Pro-6 to Glu20 and the other ranging from Tyr-24 all the way to the C-terminus Ser-50. In contrast to the results reported by Henry and Sykes [Henry, G.D., & Sykes, B.D. (1992) Biochemistry 31, 5285-5297], at a high SDS to protein ratio the protein appears to be monomeric.

NMR and circular dichroism studies of the lantibiotic nisin in non-aqueous environments.

The lantibiotic, nisin, which is known to interact with membranes of certain Gram-positive bacteria, was studied in three model systems which mimic a membrane-like environment, i.e. a mixture of trifluoroethanol and water, or micelles of sodium dodecyl sulfate or dodecylphosphocholine. The 1H NMR spectra of nisin in the non-aqueous environments, at 40 degrees C and pH 3.5, have been assigned completely. The CD and NMR results indicate that the conformation of nisin in the three non-aqueous environments differs from that in aqueous solution, and that the conformation in the two micellar systems is similar. The major conformational changes, relative to nisin in aqueous solution, occur in the N-terminus.

NMR studies of lantibiotics. The structure of nisin in aqueous solution.

Nisin is a posttranslationally modified protein of 34 amino acids, and is a member of the class of bacteriocidal polypeptides known as lantibiotics, that contain the unusual amino acid lanthionine. Its structure in aqueous solution has been determined on the basis of NMR data, i.e. interproton distance constraints derived from nuclear Overhauser enhancement spectroscopy and torsion angle constraints derived from double-quantum-filtered correlated spectroscopy. Translation of the NMR constraints into a three-dimensional structure was carried out with the distance-geometry program DISMAN, followed by restrained energy minimization using CHARMm. The internal mobility of the peptide chain prohibited the determination of a precise overall folding of the molecule, but parts of the structure could be obtained, albeit sometimes with low resolution. The structure of nisin can best be defined as follows. The outermost N-terminal and C-terminal regions of nisin appear quite flexible, the remainder of the molecule consists of an amphiphilic N-terminal fragment (residues 3-19), joined by a flexible 'hinge' region to a rigid double-ring fragment formed by residues 23-28. The latter fragment has the appearance of a somewhat overwound alpha-helix. It is suggested, by assuming the presence of a (transient) alpha-helical structure in this part of prenisin, that the coupling between residues 23 and 26, as well as between 25 and 28, by thioether bridges, and the inversion of the C alpha chiralities at positions 23 and 25, can be rationalized.

The three-dimensional structure of a DNA hairpin in solution two-dimensional NMR studies and structural analysis of d(ATCCTATTTATAGGAT).

The hairpin formed by d(ATCCTATTTATAGGAT) was studied by means of two-dimensional NMR spectroscopy and conformational analysis. Almost all 1H resonances of the stem region could be assigned, while the 1H and 31P spectra of the loop region were interpreted completely; this includes the stereospecific assignment of the H5' and H5" resonances. The derivation of the detailed loop structure was carried out in a stepwise fashion including some improved and new methods for structure determination from NMR data. In the first step, the mononucleotide structures were examined. The conformational space available to the mononucleotide was scanned systematically by varying the glycosidic torsion angle and pseudorotational parameters. Each generated conformer was tested against the experimental J coupling constants and NOE parameters. In the following stage, the structures of dinucleotides and longer fragments were derived. Inter-residue distances between protons were calculated by means of a procedure in which the simulated NOEs, obtained via a relaxation-matrix approach, were fitted to the experimental NOEs without the introduction of a molecular model. In addition, the backbone torsion angles beta, gamma and epsilon were deduced from homocoupling and heterocoupling constants. These data served as constraints in the next step, in which the loop sequence was subjected to a multi-conformer generation procedure. The resulting structures were tested against the mentioned constraints and disregarded if these constraints were violated. This yielded a family of structures for the loop region, confined to a relatively narrow conformational space. A representative conformation was subsequently docked on a B-type stem which fulfilled the structural constraints (derived from the NMR experiments for the stem region) to yield the hairpin structure. Results obtained from subsequent restrained-molecular-mechanics as well as free-molecular-mechanics calculations are in accordance with those obtained by means of the analysis described above. The structure of the hairpin loop is a compactly folded conformation and the first base of the central TTTA region forms a Hoogsteen T-A pair with the fourth base. This Hoogsteen base pair is stacked upon the sixth base pair of the B-type double-helical stem. The second base of the loop is folded into the minor groove, whereas the third base of the loop is partly stacked on the first and fourth bases. The phosphate backbone exhibits a sharp turn between the third and fourth nucleotides of the loop. The peculiar structure of this hairpin loop is discussed in relation to loop folding in DNA and RNA hairpins and in relation to a general model for loop folding.

Computer-aided assignment of the 1H-NMR spectrum of the viral-protein-genome-linked polypeptide from cowpea mosaic virus.

The 1H-NMR spectrum of the viral-protein-genome-linked (VPg) polypeptide from cowpea mosaic virus, has been interpreted via application of 2-dimensional (2D) NMR techniques. The interpretation of the data was performed by a computer program called 'PROSPECT' (PROtein SPECTra), which detects the cross-peak patterns of the amino acid residues in the spectra, assigns these patterns to amino acid types, and finally performs the sequential assignments using the well-known 'sequential walks' obtained from the NOE spectrum. Due to the severe overlap of resonances in the NMR spectrum of the VPg polypeptide, several ways of performing these walks existed. The program detected six alternatives for the sequential assignments of backbone N alpha H-C beta H-C beta H moieties.