Proline assignments and identification of the cis K116/P117 peptide bond in liganded staphylococcal nuclease using isotope edited 2D NMR spectroscopy

13C NMR Spectroscopic Studies of Intra- and Intermolecular Interactions of Amino Acid Derivatives and Peptide Derivatives in Solutions

13C NMR spectroscopic investigations were conducted for various amino acid derivatives and peptides. It was observed that 13C NMR chemical shifts of the carbonyl carbons are correlated with the solvent polarities, but the extent depends on the structures. The size of the functional groups and inter- and intra-molecular hydrogen bonding appear to be the major contributors for this tendency.

The TβR-I pre-helix extension is structurally ordered in the unbound form and its flanking prolines are essential for binding

Transforming growth factor β isoforms (TGF-β) are among the most recently evolved members of a signaling superfamily with more than 30 members. TGF-β play vital roles in regulating cellular growth and differentiation, and they signal through a highly restricted subset of receptors known as TGF-β type I receptor (TβR-I) and TGF-β type II receptor (TβR-II). TGF-β's specificity for TβR-I has been proposed to arise from its pre-helix extension, a five-residue loop that binds in the cleft between TGF-β and TβR-II. The structure and backbone dynamics of the unbound form of the TβR-I extracellular domain were determined using NMR to investigate the extension's role in binding. This showed that the unbound form is highly similar to the bound form in terms of both the β-strand framework that defines the three-finger toxin fold and the extension and its characteristic cis-Ile54-Pro55 peptide bond. The NMR data further showed that the extension and two flanking 3(10) helices are rigid on the nanosecond-to-picosecond timescale. The functional significance of several residues within the extension was investigated by binding studies and reporter gene assays in cultured epithelial cells. These demonstrated that the pre-helix extension is essential for binding, with Pro55 and Pro59 each playing a major role. These findings suggest that the pre-helix extension and its flanking prolines evolved to endow the TGF-β signaling complex with its unique specificity, departing from the ancestral promiscuity of the bone morphogenetic protein subfamily, where the binding interface of the type I receptor is highly flexible.

Prediction of Xaa-Pro peptide bond conformation from sequence and chemical shifts

We present a program, named Promega, to predict the Xaa-Pro peptide bond conformation on the basis of backbone chemical shifts and the amino acid sequence. Using a chemical shift database of proteins of known structure together with the PDB-extracted amino acid preference of cis Xaa-Pro peptide bonds, a cis/trans probability score is calculated from the backbone and (13)C(beta) chemical shifts of the proline and its neighboring residues. For an arbitrary number of input chemical shifts, which may include Pro-(13)C(gamma), Promega calculates the statistical probability that a Xaa-Pro peptide bond is cis. Besides its potential as a validation tool, Promega is particularly useful for studies of larger proteins where Pro-(13)C(gamma) assignments can be challenging, and for on-going efforts to determine protein structures exclusively on the basis of backbone and (13)C(beta) chemical shifts.

Native-like partially folded conformations and folding process revealed in the N-terminal large fragments of staphylococcal nuclease: a study by NMR spectroscopy

The N-terminal large fragments of staphylococcal nuclease (SNase), SNase110 (1-110 residues), SNase121 (1-121 residues), and SNase135 (1-135 residues), and the fragment mutants G88W110, G88W121, V66W110 and V66W121 were studied by heteronuclear multidimensional NMR spectroscopy. Ensembles of co-existent native-like partially folded and unfolded states were observed for fragments. The persistent native-like tertiary interaction drives fragments to be in partially folded states, which reveal native-like beta-barrel conformations. G88W and V66W mutations modulate the extent of inherent native-like tertiary interaction in fragment molecules, and in consequence, fragment mutants fold into native-like beta-subdomain conformations. In cooperation with the inherent tertiary interaction, 2 M TMAO (trimethylamine N-oxide) can promote the folding reaction of fragments through the changes of unfolding free energy, and a native-like beta-subdomain conformation is observed when the chain length contains 135 residues. Heterogeneous partially folded conformations of 1-121 and 1-135 fragments due to cis and trans X-prolyl bond of Lys116-Pro117 make a non-unique folding pathway of fragments. The folding reaction of fragments can be characterized as a hierarchical process.

High precision NMR structure of YhhP, a novel Escherichia coli protein implicated in cell division

YhhP, a small protein of 81 amino acid residues encoded by the yhhP gene in the Escherichia coli database, is implicated in cell division although the precise biological function of this protein has not been yet identified. A variety of microorganisms have similar proteins, all of which contain a common CPxP sequence motif in the N-terminal region. We have determined the three-dimensional solution structure of YhhP by NMR spectroscopy in order to obtain insight into its biological function. It folds into a two-layered alpha/beta-sandwich structure with a betaalphabetaalphabetabeta fold, comprising a mixed four-stranded beta-sheet stacked against two alpha-helices, both of which are nearly parallel to the strands of the beta-sheet. The CPxP motif plays a significant structural role in stabilizing the first helix as a part of the new type N-capping box where the Cys-Pro peptide bond adopts a cis configuration. The structure of YhhP displays a striking resemblance to the C-terminal ribosome-binding domain of translation initiation factor IF3 (IF3C). In addition, the surface charge distribution of the RNA-recognition helix of IF3C is nearly the same as that of the corresponding helix of YhhP. These results suggest a structure-based hypothesis in which binding to an RNA target plays an essential role in the function of this ubiquitous protein.

NMR analysis of cleaved Escherichia coli thioredoxin (1-73/74-108) and its P76A variant: cis/trans peptide isomerization

Inspection of high resolution three-dimensional (3D) structures from the protein database reveals an increasing number of cis-Xaa-Pro and cis-Xaa-Yaa peptide bonds. However, we are still far from being able to predict whether these bonds will remain cis upon single-site substitution of Pro or Yaa and/or cleavage of a peptide bond close to it in the sequence. We have chosen oxidized Escherichia coli thioredoxin (Trx), a member of the Trx superfamily with a single alpha/beta domain and cis P76 to determine the effect of single-site substitution and/or cleavage on this isomer. Standard two-dimensional (2D) NMR analysis were performed on cleaved Trx (1-73/74-108) and its P76A variant. Analysis of the NOE connectivities indicates remarkable similarity between the secondary and supersecondary structure of the noncovalent complexes and Trx. Analysis of the 2D version of the HCCH-TOCSY and HMQC-NOESY-HMQC and 13C-filtered HMQC-NOESY spectra of cleaved Trx with uniformly 13C-labeled 175 and P76 shows surprising conservation of both cis P76 and packing of 175 against W31. A similar NMR analysis of its P76A variant provides no evidence for cis A76 and shows only subtle local changes in both the packing of 175 and the interstrand connectivities between its most protected hydrophobic strands (beta2 and beta4). Indeed, a molecular simulation model for the trans P76A variant of Trx shows only subtle local changes around the substitution site. In conclusion, cleavage of R73 is insufficient to provoke cis/trans isomerization of P76, but cleavage and single-site substitution (P76A) favors the trans isomer.

Engineered disulfide bonds in staphylococcal nuclease: effects on the stability and conformation of the folded protein

Efforts to enhance the stability of proteins by introducing engineered disulfide bonds have resulted in mixed success. Most approaches to the prediction of the energetic consequences of disulfide bond formation in proteins have considered only the destabilizing effects of cross-links on the unfolded state (chain entropy model) [Pace, C. N., Grimsley, G. R., Thomson, J. A., & Barnett, B. J. (1988) J. Biol. Chem. 263, 11820-11825: Doig, A. J., & Williams, D. H. (1991) J. Mol. Biol. 217, 389-398]. It seems clear, however, that disulfide bridges also can influence the stability of the native state. In order to assess the importance of the latter effect, we have studied four variants of staphylococcal nuclease (V8 strain) each containing one potential disulfide bridge created by changing two wild-type residues to cysteines by site-directed mutagenesis. In each case, one of the introduced cysteines was within the type VIa beta turn containing cis Pro117, and the other was located in the adjacent extended loop containing Gly79. In all four cases, the overall loop size was kept nearly constant (the number of residues in the loop between the two cysteines varied from 37 to 42) so as to minimize differences from chain entropy effects. The objective was to create variants in which a change in the reduction state of the disulfide would be coupled to a change in the position of the equilibrium between the cis and trans forms of the Xxx116-Pro117 peptide bond in the folded state of the protein. The position of this equilibrium, which can be detected by NMR spectroscopy, has been shown previously to correlate with the stability of the native protein. Its determination provides a measure of strain in the folded state. The thermal stabilities and free energies for unfolding by elevated temperature and guanidinium chloride were measured for each of the four mutants under conditions in which the introduced cysteines were cross-linked (oxidized) and unlinked (reduced). In addition, reduction potentials were determined for each mutant. Formation of the different disulfide bridges was found to induce varying levels of folded state strain. The stabilization energy of a given disulfide bridge could be predicted from the measured perturbation energy for the peptide bond isomerization, provided that energetic effects on the unfolded state were calculated according to the chain entropy model. Undiagnosed strain in native states of proteins may explain the variability observed in the stabilization provided by engineered disulfide bridges.

Phosphophoryn, an "acidic" biomineralization regulatory protein: conformational folding in the presence of Cd(II)

The divalent cation-induced protein folding properties of the template macromolecule, bovine dentine phosphophoryn (BDPP), have been examined by 1H/31P/13C/113Cd-nmr spectroscopy. Cd(II) was employed, exploiting the sensitivity of 113Cd-nmr to ligand-binding interactions and kinetics. Cation binding was studied over the stoichiometric range of 0-50: 1 Cd(II): protein (mole ratio), well below the range of Cd(II) concentration required to induce protein precipitation. The stepwise titration of divalent cation-depleted phosphophoryn at pH 7.2 in H2O/D2O with 113CdCl2 revealed that (PSer)n, (PSerAsp)n, and (Asp)n polyelectrolyte cation-binding domains undergo two major transitions in their secondary and tertiary structures: the first transition, occurring between 1:10 and 1:1 Cd(II): protein stoichiometry, and the second, between 10:1 and 50:1. By monitoring the amide NH intensities, 31P-nmr chemical shift, and 13C Asp-C, resonances, it was concluded that Cd(II) ions exhibit a binding-site preference for polyelectrolyte cation-binding domains, in the order (PSer)n > (PSerAsp)n > (Asp)n This preference correlates with the degree of negative charge density for each sequence motif. Accompanying the backbone conformational transitions at the polyelectrolyte regions were conformational transitions in the flanking hinge domains, indicating that the hinge domains participate in the folding of the phosphophoryn molecule as divalent cation binding occurs at the polyelectrolyte domains. We were unsuccessful in detecting phosphophoryn-bound Cd(II) species by 113Cd-nmr because of chemical exchange modulation. However, using a smaller 21-residue peptide mimetic of phosphophoryn, we have observed three stoichiometric-dependent 113Cd resonances that differ in terms of the oxoanion coordination number. Our observation of multiple Cd(II) species in the presence of the peptide supports our contention that Cd(II) has many chemically distinct coordination sites on phosphophoryn, each in multiple equilibria with H2O, Cl-, and side-chain oxoatoms.

Phosphophoryn, a biomineralization template protein: pH-dependent protein folding experiments

The protein folding behavior of a polyelectrolyte protein, bovine dentine phosphophoryn (BDPP), in the pH range of 1.82-11.0 has been investigated. One- and two-dimensional nmr spectroscopy has been utilized to obtain proton spin assignments for amino acid residues in D2O and in H2O. One-dimensional 31P-nmr experiments verify the existence of three separate classes of O-phosphoserine (PSer) resonances in BDPP (alpha, beta, chi), representing three distinct PSer residue populations at pH 6.94. By means of pH titration and 1H-nmr, five populations of Asp residues can be identified. Three of these populations exhibit secondary inflection points on their pH titration curves that correspond to an observed pKa of 6.17-6.95. The presence or absence of secondary inflection points for Asp populations and the 31P-nmr chemical shift dispersion for the three PSer residue populations indicate that BDPP may be comprised of homologous (Asp-Asp)n. (PSer-PSer)n, and heterologous (PSer-Asp)n sequences arranged into polyelectrolyte cluster regions. The pH titration also revealed that certain populations of Ser, Gly, and Pro residues in BDPP exhibit pH-dependent resonance frequency shifts. The "apparent" pKa for the transition points of these frequency shifts corresponds to either the pK1a of Pser monophosphate ester and/or the pKa of Asp COOH group of BDPP polyelectrolyte regions. On the basis of these transition points, we can assign four types of Ser, Gly, or Pro-containing "intervening" regions in BDPP, based on their sensitivity to protonation and deprotonation events occurring at (Asp)n, (PSer)n, or (PSer-Asp)n anionic cluster regions that flank the intervening regions. Our 1H-nmr experiments also reveal that BDPP assumes a folded conformation at low pH. As the pH increases, this conformation undergoes several unfolding transitions as the BDPP molecule assumes more open conformations in response to increased electrostatic repulsion between polyelectrolyte anionic regions in the protein. These folding-unfolding transitions are mediated by the intervening regions, which act as "hinges" to allow the polyelectrolyte regions to fold relative to one another.

A peptide model for proline isomerism in the unfolded state of staphylococcal nuclease

Nuclear magnetic resonance spectroscopy has been used to investigate a synthetic peptide (YVYKPNNTHE) corresponding to residues 113 to 122 of staphylococcal nuclease. In the major folded state of the protein this region forms a type VIa beta-turn containing a cis Lys116-Pro117 peptide bond. There is, however, no evidence for any significant population of such a turn in the peptide in aqueous solution and the X-Pro bond is predominantly in the trans configuration. The peptide exhibits several well-resolved minor resonances due to the presence of a small fraction (4 +/- 2%) of the cis-proline isomer. The ratio of cis to trans isomer populations was found to be independent of temperature between 5 degrees C and 70 degrees C, indicating that delta H for the isomerism is close to zero. Using magnetization transfer techniques the rate of trans to cis interconversion was found to be 0.025(+/- 0.013) s-1 at 50 degrees C. The thermodynamics and kinetics of isomerism in the peptide are very similar to those estimated for the Lys116-Pro117 peptide bond in unfolded nuclease, suggesting that the cis-trans equilibrium in the unfolded protein is largely determined by the residues adjacent to Pro117 in the sequence. These results are consistent with previous suggestions that the cis-proline bond is stabilized late in the folding process and that the predominance of the cis form in folded nuclease is due to stabilizing interactions within the protein that give rise to a favorable enthalpy term.

Complete 1H and 13C assignment of Lys and Leu sidechains of staphylococcal nuclease using HCCH-COSY and HCCH-TOCSY 3D NMR spectroscopy

Complete proton and carbon sidechain assignments are reported for 22 lysine and 11 leucine residues in staphylococcal nuclease, an enzyme with 149 residues. These assignments are readily obtained in a direct manner from the correlations observed in the 3D HCCH-COSY and HCCH-TOCSY spectra and the known protein backbone assignments. These assignments open the way to detailed studies of the sidechain structure and dynamics at the active site, in the hydrophobic core and on the surface of the protein.

Heteronuclear 3D NMR and isotopic labeling of calmodulin. Towards the complete assignment of the 1H NMR spectrum

New methods are described that permit detailed analysis of the NMR spectra of calmodulin, an alpha-helical protein with a molecular weight of 16.7 kD. Two complementary approaches have been used: uniform labeling with 15N and labeling of specific amino acids with either 15N or 13C. It is demonstrated that uniform 15N labeling permits the recording of sensitive three-dimensional (3D) NMR spectra that show far better resolution than their conventional two-dimensional analogs. Selective 15N labeling of amino acids can be used for identifying the type of amino acid, providing information that is essential for the analysis of the 3D spectra. Simultaneous selective labeling with both 15N and 13C can provide a number of unique backbone assignments from which sequential assignment can be continued.