Structure-function relationships of human C5a and C5aR

Using peptides that represent linear regions of the powerful complement activation product, C5a, or loops that connect the four alpha helices of C5a, we have defined the ability of these peptides to reduce binding of (125)I-C5a to human neutrophils, inhibit chemotactic responses of neutrophils to C5a, and reduce H(2)O(2) production in neutrophils stimulated with PMA. The data have defined likely sites of interaction of C5a with C5aR. The peptides had no functional activity per se on neutrophils and did not interfere with neutrophil responses to the unrelated chemotactic peptide, N-formyl-Met-Leu-Phe. Although previous data have suggested that there are two separate sites on C5a reactive with C5aR, the current data suggest that C5a interacts with C5aR in a manner that engages three discontinuous regions of C5a.

Structure of the type III secretion and substrate-binding domain of Yersinia YopH phosphatase

Pathogenic strains of Yersinia deploy a type III secretion system to inject the potent tyrosine phosphatase YopH into host cells, where it dephosphorylates focal adhesion-associated substrates. The amino-terminal, non-catalytic domain of YopH is bifunctional; it is essential for the secretion and binding of the specific chaperone SycH, but also targets the catalytic domain to substrates in the infected cell. We describe the 2.2 A resolution crystal structure of residues 1-129 of YopH from Yersinia pseudotuberculosis. The amino-terminal alpha-helix (2-17), comprising the secretion signal, and beta-strand (24-28) of one molecule exchange with another molecule to form a domain-swapped dimer. Nuclear magnetic resonance (NMR) and gel filtration experiments demonstrated that YopH(1-129) could exist as a monomer and/or a dimer in solution. The topology of the dimer and the dynamics of a monomeric form in solution observed by NMR imply that YopH has the propensity to unfold partially. The dimer is probably not important physiologically, but may mimic how SycH binds to the exposed non-polar surfaces of a partially unfolded YopH. Phosphopeptide-induced perturbations in NMR chemical shifts define a substrate-binding surface on YopH(1-129) that includes residues previously shown by mutagenesis to be essential for YopH function.

Delineation of the allosteric mechanism of a cytidylyltransferase exhibiting negative cooperativity

The dimeric enzyme CTP:glycerol-3-phosphate cytidylyltransferase (GCT) displays strong negative cooperativity between the first and second binding of its substrate, CTP. Using NMR to study the allosteric mechanism of this enzyme, we observe widespread chemical shift changes for the individual CTP binding steps. Mapping these changes onto the molecular structure allowed the formulation of a detailed model of allosteric conformational change. Upon the second step of ligand binding, NMR experiments indicate an extensive loss of conformational exchange broadening of the backbone resonances of GCT. This suggests that a fraction of the free energy of negative cooperativity is entropic in origin.

Mapping the interactions between flavodoxin and its physiological partners flavodoxin reductase and cobalamin-dependent methionine synthase

Flavodoxins are electron-transfer proteins that contain the prosthetic group flavin mononucleotide. In Escherichia coli, flavodoxin is reduced by the FAD-containing protein NADPH:ferredoxin (flavodoxin) oxidoreductase; flavodoxins serve as electron donors in the reductive activation of anaerobic ribonucleotide reductase, biotin synthase, pyruvate formate lyase, and cobalamin-dependent methionine synthase. In addition, domains homologous to flavodoxin are components of the multidomain flavoproteins cytochrome P450 reductase, nitric oxide synthase, and methionine synthase reductase. Although three-dimensional structures are known for many of these proteins and domains, very little is known about the structural aspects of their interactions. We address this issue by using NMR chemical shift mapping to identify the surfaces on flavodoxin that bind flavodoxin reductase and methionine synthase. We find that these physiological partners bind to unique overlapping sites on flavodoxin, precluding the formation of ternary complexes. We infer that the flavodoxin-like domains of the cytochrome P450 reductase family form mutually exclusive complexes with their electron-donating and -accepting partners, complexes that require conformational changes for interconversion.

Functional dynamics in the active site of the ribonuclease binase

Binase, a member of a family of microbial guanyl-specific ribonucleases, catalyzes the endonucleotic cleavage of single-stranded RNA. It shares 82% amino acid identity with the well-studied protein barnase. We used NMR spectroscopy to study the millisecond dynamics of this small enzyme, using several methods including the measurement of residual dipolar couplings in solution. Our data show that the active site of binase is flanked by loops that are flexible at the 300-micros time scale. One of the catalytic residues, His-101, is located on such a flexible loop. In contrast, the other catalytic residue, Glu-72, is located on a beta-sheet, and is static. The residues Phe-55, part of the guanine base recognition site, and Tyr-102, stabilizing the base, are the most dynamic. Our findings suggest that binase possesses an active site that has a well-defined bottom, but which has sides that are flexible to facilitate substrate access/egress, and to deliver one of the catalytic residues. The motion in these loops does not change on complexation with the inhibitor d(CGAG) and compares well with the maximum k(cat) (1,500 s(-1)) of these ribonucleases. This observation indicates that the NMR-measured loop motions reflect the opening necessary for product release, which is apparently rate limiting for the overall turnover.

An iterative fitting procedure for the determination of longitudinal NMR cross-correlation rates

We present a method to measure (15)N-(1)H dipolar/(15)N CSA longitudinal cross-correlation rates in protonated proteins. The method depends on the measurement of four observables: the cumulative proton-proton cross relaxation rates, the (15)N R(1) relaxation rate, the multiexponential decay of 2N(Z)H(N)(Z) spin-order, and multiexponential buildup of 2N(Z)H(N)(Z) spin-order. The (15)N-(1)H dipolar/(15)N CSA longitudinal cross-correlation rate is extracted from these measurements by an iterative fitting procedure to the solution of differential equations describing the coupled relaxation dynamics of the z-magnetization of the (15)N nucleus, the two-spin-order 2N(Z)H(N)(Z), and a two-spin-order term 2N(Z)H(Q)(Z) describing the interaction with remote protons. The method is applied to the microbial ribonuclease binase. The method can also extract longitudinal cross-correlation rates for those amide protons that are involved in rapid solvent exchange. The experiment that serves for extracting proton-proton cross-relaxation rates is a modification of 3D (15)N-resolved NOESY-HSQC. The experiment restores the solvent magnetization to its equilibrium state during data detection for all phase cycling steps and all values of NOE mixing times and is recommended for use in standard applications as well.

Structural insights into substrate binding by the molecular chaperone DnaK

How substrate affinity is modulated by nucleotide binding remains a fundamental, unanswered question in the study of 70 kDa heat shock protein (Hsp70) molecular chaperones. We find here that the Escherichia coli Hsp70, DnaK, lacking the entire alpha-helical domain, DnaK(1-507), retains the ability to support lambda phage replication in vivo and to pass information from the nucleotide binding domain to the substrate binding domain, and vice versa, in vitro. We determined the NMR solution structure of the corresponding substrate binding domain, DnaK(393-507), without substrate, and assessed the impact of substrate binding. Without bound substrate, loop L3,4 and strand beta3 are in significantly different conformations than observed in previous structures of the bound DnaK substrate binding domain, leading to occlusion of the substrate binding site. Upon substrate binding, the beta-domain shifts towards the structure seen in earlier X-ray and NMR structures. Taken together, our results suggest that conformational changes in the beta-domain itself contribute to the mechanism by which nucleotide binding modulates substrate binding affinity.

Magnetization transfer via residual dipolar couplings: application to proton-proton correlations in partially aligned proteins

A novel three-dimensional NMR experiment is reported that allows the observation of correlations between amide and other protons via residual dipolar couplings in partially oriented proteins. The experiment is designed to permit quantitative measurement of the magnitude of proton-proton residual dipolar couplings in larger molecules and at higher degree of alignments. The observed couplings contain data valuable for protein resonance assignment, local protein structure refinement, and determination of low-resolution protein folds.

Line narrowing in spectra of proteins dissolved in a dilute liquid crystalline phase by band-selective adiabatic decoupling: application to 1HN-15N residual dipolar coupling measurements

Residual heteronuclear dipolar couplings obtained from partially oriented protein samples can provide unique NMR constraints for protein structure determination. However, partial orientation of protein samples also causes severe 1H line broadening resulting from residual 1H-1H dipolar couplings. In this communication we show that band-selective 1H homonuclear decoupling during data acquisition is an efficient way to suppress residual 1H-1H dipolar couplings, resulting in spectra that are still amenable to solution NMR analysis, even with high degrees of alignment. As an example, we present a novel experiment with improved sensitivity for the measurement of one-bond 1HN-15N residual dipolar couplings in a protein sample dissolved in magnetically aligned liquid crystalline bicelles.

Secondary structure and fold homology of the ArsC protein from the Escherichia coli arsenic resistance plasmid R773

Resistance to several toxic anions in Escherichia coli is conferred by the ars operon carried on plasmid R773. The gene products of this operon catalyze extrusion of antimonials and arsenicals from cells. In this paper, we report the determination of the overall fold for ArsC, a 16 kDa protein of the ars operon involved in the reduction of arsenate to arsenite, using multidimensional, multinuclear NMR. The protein is found to contain large regions of extensive mobility, particularly in the active site. A model fold, computed on the basis of a preliminary set of NOEs, was found to be structurally homologous to E. coli glutaredoxin, thiol transferases, and glutathione S-transferase. Some kinship to the structure of low molecular weight tyrosine phosphatases, based on rough topological similarity but more so on the basis of a common anion-binding-loop motif H-CX(n)R, was also detected. Although functional, secondary, and tertiary structural homology is observed with these molecules, no significant homology in primary structure was detected. The mobilities of the active site of ArsC and of other enzymes are discussed.

High-resolution four-dimensional HMQC-NOESY-HSQC spectroscopy

Practical optimization of the 4D [(1)H, (13)C, (13)C, (1)H] HMQC-NOESY-HSQC experiment in terms of distribution of resolution over the indirect dimensions is analyzed in detail. Recommendations for an optimal experiment are based on computer simulations assessing the effective resolution of the experiment, defined as the percentage of all possible NOE cross peaks that can be assigned unambiguously on the basis of the spectral data alone. Using actual (13)C-(1)H spectra of an 18-kDa chaperone protein, the analysis shows that experiments with the best effective resolution are also among the most sensitive ones. When combined with an efficient aliasing scheme that reduces indirect spectral space 124-fold, a 4D experiment that yields unambiguous assignments for 41% of all possible NOE cross peaks can be recorded in 28 h. A high-resolution experiment, which can be recorded in 8 days, yields 61% unambiguous assignments and can be analyzed more easily using standard NMR display software. The predictions are verified with experimental 4D spectra from which 1850 NOEs (914 long-range) were extracted for the 18-kDa chaperone protein.

High-resolution solution structure of the 18 kDa substrate-binding domain of the mammalian chaperone protein Hsc70

The three-dimensional structure for the substrate-binding domain of the mammalian chaperone protein Hsc70 of the 70 kDa heat shock class (HSP70) is presented. This domain includes residues 383-540 (18 kDa) and is necessary for the binding of the chaperone with substrate proteins and peptides. The high-resolution NMR solution structure is based on 4150 experimental distance constraints leading to an average root-mean-square precision of 0.38 A for the backbone atoms and 0.76 A for all atoms in the beta-sandwich sub-domain. The protein is observed to bind residue Leu539 in its hydrophobic substrate-binding groove by intramolecular interaction. The position of a helical latch differs dramatically from what is observed in the crystal and solution structures of the homologous prokaryotic chaperone DnaK. In the Hsc70 structure, the helix lies in a hydrophobic groove and is anchored by a buried salt-bridge. Residues involved in this salt-bridge appear to be important for the allosteric functioning of the protein. A mechanism for interdomain allosteric modulation of substrate-binding is proposed. It involves large-scale movements of the helical domain, redefining the location of the hinge area that enables such motions.

Characterizing semilocal motions in proteins by NMR relaxation studies

The understanding of protein function is incomplete without the study of protein dynamics. NMR spectroscopy is valuable for probing nanosecond and picosecond dynamics via relaxation studies. The use of 15N relaxation to study backbone dynamics has become virtually standard. Here, we propose to measure the relaxation of additional nuclei on each peptide plane allowing for the observation of anisotropic local motions. This allows the nature of local motions to be characterized in proteins. As an example, semilocal rotational motion was detected for part of a helix of the protein Escherichia coli flavodoxin.

NMR solution structure of the 21 kDa chaperone protein DnaK substrate binding domain: a preview of chaperone-protein interaction

The solution structure of the 21 kDa substrate-binding domain of the Escherichia coli Hsp70-chaperone protein DnaK (DnaK 386-561) has been determined to a precision of 1.00 A (backbone of the beta-domain) from 1075 experimental restraints obtained from multinuclear, multidimensional NMR experiments. The domain is observed to bind to its own C-terminus and offers a preview of the interaction of this chaperone with other proteins. The bound protein region is tightly held at a single amino acid position (a leucyl residue) that is buried in a deep pocket lined with conserved hydrophobic residues. A second hydrophobic binding site was identified using paramagnetically labeled peptides. It is located in a region close to the N-terminus of the domain and may constitute the allosteric region that links substrate-binding affinity with nucleotide binding in the Hsp70 chaperones.

Structural analysis of the P10/11-P12 RNA domain of yeast RNase P RNA and its interaction with magnesium

The P10/11-P12 RNA domain of yeast RNase P contains several highly conserved nucleotides within a conserved secondary structure. This RNA domain is essential for enzyme function in vivo, where it has a demonstrated role in divalent cation utilization. To better understand the function of this domain, its structure and alterations in response to magnesium have been investigated in vitro. A secondary structure model of the P10/11-P12 RNA domain had been previously developed by phylogenetic analysis. Computer modeling and energy minimization were applied to the Saccharomyces cerevisiae P10/11-P12 domain to explore alternatives and additional interactions not predicted by the phylogenetic consensus. The working secondary structure models were challenged with data obtained from 1H NMR and in vitro chemical and enzymatic probing experiments. The solution structure of the isolated domain was found to conform to the phylogenetic prediction within the context of the holoenzyme. Structure probing data also discriminated among additional base contacts predicted by energy minimization. The withdrawal of magnesium does not appear to cause gross refolding or rearrangement of the RNA domain structure. Instead, subtle changes occur in the solution accessibility of specific nucleotide positions. Most of the conserved nucleotides reported to be involved in magnesium utilization in vivo also display magnesium-dependent changes in vitro.

High-resolution detection of five frequencies in a single 3D spectrum: HNHCACO--a bidirectional coherence transfer experiment

A new triple-resonance pulse sequence, 3D HNHCACO, is introduced and discussed, which identifies sequential correlations of the backbone nuclei (H alpha (i-1), C alpha (i-1), C(i-1), NH(i), N(i)) of doubly labeled proteins in H2O. The three-dimensional (3D) method utilizes a recording of 15N and 13C resonances in a single indirect time domain, the 13C' resonance in another indirect time domain, and detects both NH and H alpha protons. A bidirectional coherence transfer (NH(i) <--> N(i) <--> C(i-1) <--> C alpha (i-1) <--> H alpha (i-1)) is effectuated, resulting in a single high-resolution 3D spectrum that contains the frequencies of all five backbone nuclei. The experiment was applied to the 12.3 kDa ribonuclease from Bacillus intermedius (Binase).

Identification of functional conserved residues of CTP:glycerol-3-phosphate cytidylyltransferase. Role of histidines in the conserved HXGH in catalysis

The CTP:glycerol-3-phosphate cytidylyltransferase (GCT) of Bacillus subtilis has been shown to be similar in primary structure to the CTP:phosphocholine cytidylyltransferases of several organisms. To identify the residues of this cytidylyltransferase family that function in catalysis, the conserved hydrophilic amino acid residues plus a conserved tryptophan of the GCT were mutated to alanine. The most dramatic losses in activity occurred with H14A and H17A; these histidine residues are part of an HXGH sequence similar to that found in class I aminoacyl-tRNA synthetases. The kcat values for H14A and H17A were decreased by factors of 5 x 10(-5) and 4 x 10(-4), respectively, with no significant change in Km values. Asp-11, which is found near the HXGH sequence in the cytidylyltransferases but not aminoacyl-tRNA synthetases, was also important for activity, with the D11A mutation decreasing activity by a factor of 2 x 10(-3). Several residues found in the sequence RTEGISTT, a signature sequence for this cytidylyltransferase family, as well as other isolated residues were also shown to be important for activity, with kcat values decreasing by factors of 0.14-4 x 10(-4). The Km values of three mutant enzymes, D38A, W74A, and D94A, for both CTP and glycerol-3-phosphate were 6-130-fold higher than that of the wild-type enzyme. Mutant enzymes were analyzed by two-dimensional NMR to determine if the overall structures of the enzymes were intact. One of the mutant enzymes, D66A, was defective in overall structure, but several of the others, including H14A and H17A, were not. These results indicate that His-14 and His-17 play a role in catalysis and suggest that their role is similar to the role of the His residues in the HXGH sequence in class I aminoacyl-tRNA synthetases, i.e. to stabilize a pentacoordinate transition state.

Protein heteronuclear NMR assignments using mean-field simulated annealing

A computational method for the assignment of the NMR spectra of larger (21 kDa) proteins using a set of six of the most sensitive heteronuclear multidimensional nuclear magnetic resonance experiments is described. Connectivity data obtained from HNC alpha, HN(CO)C alpha, HN(C alpha)H alpha, and H alpha (C alpha CO)NH and spin-system identification data obtained from CP-(H)CCH-TOCSY and CP-(H)C(C alpha CO)NH-TOCSY were used to perform sequence-specific assignments using a mean-field formalism and simulated annealing. This mean-field method reports the resonance assignments in a probabilistic fashion, displaying the certainty of assignments in an unambiguous and quantitative manner. This technique was applied to the NMR data of the 172-residue peptide-binding domain of the E. coli heat-shock protein, DnaK. The method is demonstrated to be robust to significant amounts of missing, spurious, noisy, extraneous, and erroneous data.

Band-selective hetero- and homonuclear cross-polarization using trains of shaped pulses

The performance of solution cross-polarization using trains of shaped pulses on two channels is investigated by computer simulation and experiment. It is determined that a Waltz modulation pattern of Gaussian pulses of individual flip angles of 225°, issued to two coupled spins simulatneously, yields excellent coherence transfer with good phasing behavior. Simulations and experimental verification were carried out for both heteronuclear cross-polarization between two restricted areas (e.g. (1)H(α)-(13)C(α)) and for homonuclear cross-polarization between two spectral regions (e.g. (13)CO-(13)C(α)). It is shown that shaped cross-polarization behaves as pure heteronuclear cross-polarization when the two radiofrequency (rf) fields are far apart, while it behaves in some aspects analogous to homonuclear cross-polarization when the two rf fields approach each other. The novel coherence-transfer sequence, referred to as 'cosine-modulated shaped Waltz' (CSW), was implemented in a 3D (H)C(CCO)NH experiment using an 18-kDa isotopically labeled protein.

Study of protein dynamics in solution by measurement of (13)C (α)- (13)CO NOE and (13)CO longitudinal relaxation

(13)C(α)-(13)CO homonuclear NOE and (13)CO T(1) relaxation were measured for a 20 kDa protein using tripleresonance pulse sequences. The experiments were sufficiently sensitive to obtain statistically significant differences in relaxation parameters over the molecule. The (13)C(α)-(13)CO cross-relaxation rate, obtained from these data, is directly proportional to an order parameter describing local motion and it is largely independent of the local correlation time. It is therefore a relatively straightforward observable for the identification of local dynamics.

Solution structure of the catalytic domain of human stromelysin complexed with a hydrophobic inhibitor

Stromelysin, a representative matrix metalloproteinase and target of drug development efforts, plays a prominent role in the pathological proteolysis associated with arthritis and secondarily in that of cancer metastasis and invasion. To provide a structural template to aid the development of therapeutic inhibitors, we have determined a medium-resolution structure of a 20-kDa complex of human stromelysin's catalytic domain with a hydrophobic peptidic inhibitor using multinuclear, multidimensional NMR spectroscopy. This domain of this zinc hydrolase contains a mixed beta-sheet comprising one antiparallel strand and four parallel strands, three helices, and a methionine-containing turn near the catalytic center. The ensemble of 20 structures was calculated using, on average, 8 interresidue NOE restraints per residue for the 166-residue protein fragment complexed with a 4-residue substrate analogue. The mean RMS deviation (RMSD) to the average structure for backbone heavy atoms is 0.91 A and for all heavy atoms is 1.42 A. The structure has good stereochemical properties, including its backbone torsion angles. The beta-sheet and alpha-helices of the catalytic domains of human stromelysin (NMR model) and human fibroblast collagenase (X-ray crystallographic model of Lovejoy B et al., 1994b, Biochemistry 33:8207-8217) superimpose well, having a pairwise RMSD for backbone heavy atoms of 2.28 A when three loop segments are disregarded. The hydroxamate-substituted inhibitor binds across the hydrophobic active site of stromelysin in an extended conformation. The first hydrophobic side chain is deeply buried in the principal S'1 subsite, the second hydrophobic side chain is located on the opposite side of the inhibitor backbone in the hydrophobic S'2 surface subsite, and a third hydrophobic side chain (P'3) lies at the surface.

Occurrence, solution structure and stability of DNA hairpins stabilized by a GA/CG helix unit

The occurrence and NMR solution structure of a class of biloop hairpins containing the sequence 5'-CGXYAG are presented. These hairpins, which are variations on a sequence found in the reverse transcript of the human T-cell leukemia virus 2 (HLV2), show elevated melting points and high chemical stability toward denaturation by urea. Hairpins with the 5'-CGXYAG configuration have melting points 18-20 degrees higher than hairpins with 5'-CAXYGG or 5'-GGXYAC configurations. The identities of the looping bases, X and Y above, play a negligible role in determining the stability of this DNA hairpin stability. This is very different from G-A based loops in RNA, where the third base must be a purine for high stability [the GNRA loops; V.P. Antao, S.Y. Lai and I. Tinoco, Jr (1991) Nucleic Acids Res., 19, 5901-5905]. We show that these properties are associated with a four base helix unit that contains both a sheared GA base pair and a Watson-Crick CG base pair upon which it is stacked. As an understanding of the significance of AG base pairs has become increasingly important in the structural biology of nucleic acids, we compute an 0.7-0.9 A precision ensemble of NMR solution structures using iterative relaxation matrix methods. Calculations performed on NMR-derived structures indicate that neither base-base electrostatic interactions, nor base-solvent dispersive interactions, are significant factors in determining the observed differences in hairpin stability. Thus the stability of the 5'-CGXYAG configuration would appear to derive from favorable base-base London/van der Waals interactions.

15N, 13C, and 1H NMR assignments and secondary structure for T4-lysozyme

Sequence-specific 1H, 13C, and 15N backbone assignments and 1H and 13C side-chain assignments have been identified for T4-lysozyme (164 residues, MW = 18.7 kDa). A variety of double- and triple-resonance 3D techniques were used. Some of these methods were applied in unconventional ways and a detailed description of the advantages and disadvantages of these approaches is given. Complete backbone resonances for 162 of the 164 residues and partial assignments for the remaining 2 residues were obtained. The 1H and 15N assignments are in agreement with those obtained previously by McIntosh et al. who used selective labeling (L.P. McIntosh et al., Biochemistry 29, 6341 (1990)). Complete proton and carbon side-chain assignments were made for 120 residues and partial side-chain assignments were made for 42 additional residues. A qualitative analysis of the medium-range NOESY data reveals a secondary structure consistent with the X-ray crystallographic structure.

Solution structure of a DNA hairpin and its disulfide cross-linked analog

The solution structures of a 21 base long DNA hairpin derived from the ColE1 cruciform, and an analog possessing a disulfide cross-link bridging the terminal bases, have been determined by NMR spectroscopy. The 8 bp long stem of these sequences adopts a B-form helix whereas the five base long single-stranded loop appears to be flexible and cannot be represented by a unique static conformation. NOESY cross-peak volumes, proton and phosphorus chemical shifts, and both homo- and heteronuclear coupling constants for the cross-linked hairpin are virtually identical to those measured for the unmodified sequence, even for the residues that are proximal to the cross-link. These results indicate that both hairpins are structurally isomorphous. Because this cross-link can be incorporated site specifically in a sequence independent manner, and does not appear to alter native conformation, it should prove broadly applicable in studies of DNA structure and function.

The peptide-binding domain of the chaperone protein Hsc70 has an unusual secondary structure topology

Modern NMR methods were used to determine the secondary structure topology of the 18 kDa peptide binding domain of the chaperone protein Hsc70 in solution. This report constitutes the first experimental conformational information on this important domain of the class of Hsp70 proteins. The domain consists of two four-stranded antiparallel beta-sheets and a single alpha-helix. The topology does not resemble at all the topology observed in the human leukocyte antigen (HLA) proteins of the major histocompatibility complex. This is significant because such resemblance was predicted on the basis of limited amino acid homology, secondary structure prediction, and related function. Moreover, the exact meander-type beta-sheet topology identified in Hsc70 has to our best knowledge not been observed in any other known protein structure.

HCCH-TOCSY spectroscopy of 13C-labeled proteins in H2O using heteronuclear cross-polarization and pulsed-field gradients

A pulsed-field gradient-enhanced, heteronuclear cross-polarization-driven, 3D HCCH-TOCSY experiment is described, which in a single scan can achieve nearly ideal solvent suppression for protein samples in H2O solution. The 3D experiment can be transformed without additional pre- or post-processing, thus leaving solute resonances at the solvent resonance position undisturbed and easily identifiable. As the gradients are used in combination with a 13C z-filter, only minimal relaxation losses are encountered as compared to non-gradient versions.

Assignments for the main-chain nuclear magnetic resonances and delineation of the secondary structure of the catalytic domain of human stromelysin-1 as obtained from triple-resonance 3D NMR experiments

We report the NMR assignments for the main-chain 13C, 15N, and 1H resonances (1HN, 1H alpha, 15N alpha, 13C alpha, 13CO) for the 19.5-kDa catalytic domain of human stromelysin-1, a zinc endoproteinase thought to be involved in pathologic tissue degradation. The assignments were predominantly obtained from triple-resonance three-dimensional NMR experiments using double-labeled (15N/13C) samples. The secondary structure of the molecule was determined from analysis of 3D 15N-resolved NOESY experiments. It was found to consist of a five-stranded mixed beta-sheet with four parallel and one antiparallel strand and three helices. The topological arrangement of the secondary structure elements of stromelysin catalytic domain is remarkably similar to that found for astacin, a Zn proteinase for which the tertiary structure was recently determined from X-ray diffraction data [Bode et al. (1992) Nature 358, 164-167].

Characterization of a posttranslational fucosylation in the growth factor domain of urinary plasminogen activator

A posttranslational modification site in natural and recombinant urinary-type plasminogen activators (urokinases; EC 3.4.21.31) has been localized to Thr-18, in the growth factor domain of the molecule. This is the region of urinary plasminogen activator responsible for its specific receptor binding. An unusual carbohydrate-protein linkage, a single monosaccharide, fucose, covalently attached directly to threonine in the peptide, is described here. The glycan moiety and the site of modification have been identified with mass spectrometry and confirmed by carbohydrate composition analysis, Edman degradation, and one- and two-dimensional NMR studies. This type of modification is normally not detected without mass spectrometry because the fucose-threonine bond is hydrolyzed under standard acidic conditions of the amino acid analysis and Edman sequencing. This modification may be widely found in other proteins.

NMR methods for determining the structures of enzyme/inhibitor complexes as an aid in drug design

Four approaches are described for providing detailed structural information on large enzyme/inhibitor complexes to aid in the design of improved enzyme inhibitors. In one approach, proton NMR spectra are simplified by isotope-editing procedures in which only those protons that are attached to isotopically labeled nuclei (e.g. 13C or 15N) and their scalar or dipolar coupled partners are observed. Using this strategy, the conformation of an inhibitor bound to porcine pepsin can be determined and structural information on the active site obtained. In another approach, two-dimensional nuclear Overhauser effect (2D NOE) difference spectra are obtained by subtracting NOE spectra of two enzyme/inhibitor complexes prepared with either a protonated or a deuterated inhibitor. Only NOEs arising from protons of the inhibitor substituted with deuterium appear in the 2D NOE difference spectra as illustrated for a pepsin/inhibitor complex. In a third strategy, deuterated enzymes are employed to eliminate the many proton NMR signals of the enzyme and allow the selective detection of the resonances corresponding to the bound ligand as demonstrated for CTP bound to CMP-3-deoxy D-manno-octulosonic acid (KDO) synthetase. Finally, a fourth approach is described using heteronuclear three-dimensional NMR spectroscopy in which homonuclear 2D NMR spectra are edited with respect to the heteronuclear chemical shifts. Using these methods the complete three-dimensional structures of large enzyme/inhibitor complexes can potentially be obtained. Examples of the spectral simplification that can be achieved using 3D NMR are given for 15N-labeled CMP-KDO synthetase complexed with an inhibitor and CTP.

Heteronuclear three-dimensional NMR spectroscopy of isotopically labelled biological macromolecules

Due to the development of two-dimensional Fourier transformation techniques (for reviews see Bax, 1982; Ernst et al. 1987), NMR spectroscopy has become a powerful tool for determining the 3D structures of small proteins (MW ≤ 10 kDa); for reviews see Wüthrich, 1986; Clore & Gronenborn, 1987. For larger molecules, however, the amount of detailed structural information that can be obtained using homonuclear 2D NMR techniques is limited because of the vast number of overlapping signals. In order to extend the capabilities of NMR to the study of larger systems, new approaches are required.

Heteronuclear three-dimensional NMR spectroscopy of the inflammatory protein C5a

The utility of three-dimensional heteronuclear NMR spectroscopy for the assignment of 1H and 15N resonances of the inflammatory protein C5a (MW 8500), uniformly labeled with 15N, is demonstrated at a protein concentration of 0.7 mM. It is shown that dramatic simplification of the 2D nuclear Overhauser effect spectrum (NOESY) is obtained by editing with respect to the frequency of the 15N heteronucleus in a third dimension. The improved resolution in the 3D experiment largely facilitates the assignment of protein NMR spectra and allows for the determination of distance constraints from otherwise overlapping NOE cross peaks for purposes of 3D structure determination. The results show that 15N heteronuclear 3D NMR can facilitate the structure determination of small proteins and promises to be a useful tool for the study of larger systems that cannot be studied by conventional 2D NMR techniques.

Heteronuclear three-dimensional NMR spectroscopy applied to CMP-KDO synthetase (27.5 kD)

A heteronuclear three-dimensional NMR experiment has been applied to uniformly 15N-labeled CMP-KDO synthetase (CTP:3-deoxy-D-manno-octulosonate cytidylyl transferase; E.C. 2.7.7.38) complexed with an inhibitor and CTP. Using this 3D technique, the 2D NOE spectrum of the ternary complex was dramatically simplified by editing with respect to the 15N frequencies of the labeled enzyme. This 3D NMR method is a useful tool for resolving spectral overlap and is particularly well-suited for NMR studies of large molecules which are difficult to study by conventional 2D NMR techniques.

Tertiary structure of human complement component C5a in solution from nuclear magnetic resonance data

The tertiary structure for the region 1-63 of the 74 amino acid human complement protein C5a in solution was calculated from a large number of distance constraints derived from nuclear Overhauser effects with an angular distance geometry algorithm. The protein consists of four helices juxtaposed in an approximately antiparallel topology connected by peptide loops located at the surface of the molecule. The structures obtained for the helices are compatible with alpha-helical hydrogen-bonding patterns, which provides an explanation for the observed slow solvent exchange kinetics of the amide protons in these peptide regions. In contrast to the peptide region 1-63, no defined structure could be assigned to the C-terminal region 64-74, which increasingly acquires dynamic random coil characteristics as the end of the peptide chain is approached. An average root-mean-square deviation of 1.6 A was obtained for the alpha-carbons of the first 63 residues in the calculated ensemble of C5a structures, while the alpha-helices were determined with an average root-mean-square deviation of 0.8 A for the alpha-carbons. A comparison between the solution structure of C5a and the crystal structure of the functionally related C3a protein, as well as inferences for the interaction of C5a with its receptor on polymorphonuclear leukocytes, is discussed.

Identification of receptor-binding residues in the inflammatory complement protein C5a by site-directed mutagenesis

C5a is an inflammatory mediator potentially involved in a number of diseases. To help define which of its 74 residues are important for receptor binding and response triggering, changes in the amino acid sequence of C5a were introduced by site-directed mutagenesis. Synthetic C5a-encoding genes incorporating point mutations were expressed in Escherichia coli, and the mutant proteins were purified to homogeneity. Modifications of the C5a molecule causing parallel reductions in binding to polymorphonuclear leukocyte membranes and in stimulation of polymorphonuclear leukocyte locomotion (chemokinesis) suggest that carboxyl-terminal residues Lys-68, Leu-72, and Arg-74 interact with the receptor. Substitutions in the disulfide-linked core of C5a revealed involvement of Arg-40 or nearby residues, because potency losses were associated with only localized conformational changes as detected by NMR. Surprisingly, a substitution at core residue Ala-26, which did not alter C5a core structure, appeared from NMR results to reduce potency by causing a long-distance conformational change centered on residue His-15. Thus, at least three discontinuous regions of the C5a molecule appear to act in concert to achieve full potency.

Secondary structure of complement component C3a anaphylatoxin in solution as determined by NMR spectroscopy: differences between crystal and solution conformations

Two-dimensional 1H NMR investigations were used to locate elements of regular secondary structure in the human complement protein C3a (the des-Arg77 derivative) in solution. The results were compared to a refined crystal structure based on the 3.2-A resolution structure of des-Arg77-C3a [Huber, R., Scholze, H., Paques, E. P. & Deisenhofer, J. (1980) Hoppe-Seyler's Z. Physiol. Chem. 361, 1389-1399]. In excellent agreement with the x-ray data, helices occur in the regions of residues 17-28 and 36-43 in solution. In contrast to the x-ray data, where a third long helix was found from residue 47 to residue 73, the solution data show a shorter helix in the region from residue 47 to residue 66, followed by a transition range at positions 67-70, leading into a six-residue carboxyl-terminal peptide in dynamic random coil conformation. At the amino terminus, a well-defined helix is observed in solution for the residues 8-15 region, which, like the carboxyl terminus, gradually changes to dynamic random coil toward the end of the polypeptide chain. This is at variance with the x-ray data as well, in which residues 13-15 are nonhelical and no electron density could be assigned to the first 12 residues due to disorder.

Sequence-specific assignments in the 1H NMR spectrum of the human inflammatory protein C5a

Full sequence-specific assignments for the 1H NMR lines of the backbone protons of the human complement factor C5a are described and documented. The results were obtained by largely following the methodology developed by Wüthrich et al. [Wüthrich, K., Wider, G., Wagner, G., & Braun, W. (1982) J. Mol. Biol. 155, 311]. Assignments for the majority of the amino acid side chain protons were obtained by using a comparison of double- and triple-quantum-filtered two-dimensional correlated experiments together with the analysis of relayed coherence transfer spectra. The assignments provide the basis for the determination of the thus far unknown three-dimensional structure of C5a from nuclear Overhauser enhancement distance constraints.

Comparison of model and nuclear magnetic resonance structures for the human inflammatory protein C5a

The model structure previously proposed for human C5a, based upon the crystal structure of the homologous protein human C3a, is compared to the solution structure of human C5a recently determined by nuclear magnetic resonance (NMR) methods in our laboratory. The general folding and helix topography of the C5a protein were modeled very well. The N-terminus, which is disordered in the C3a crystal, was correctly predicted in the C5a model both as to its being a helix and as to its docking site on the rest of the molecule. On the other hand, the NMR data show that the biologically important C-terminal residues are disordered in solution, unlike the model and the C3a crystal structure where this region was helical.

Determination of protein structures from nuclear magnetic resonance data using a restrained molecular dynamics approach: the lac repressor DNA binding domain

A procedure is described to determine from NMR data the three-dimensional structure of biomolecules. This procedure combines model building with a restrained Molecular Dynamics algorithm, in which distance information from NOEs is incorporated in the form of pseudo potentials. The method has been applied to the N-terminal DNA-binding domain or "headpiece" (amino acids 1-51) of the lac repressor from E. coli, for which no crystal structure is available. The spatial structure of the headpiece is discussed in terms of known physical and biochemical data and of its DNA binding properties.

A protein structure from nuclear magnetic resonance data. lac repressor headpiece

A procedure is described to determine the three-dimensional structure of biomolecules from nuclear magnetic resonance data. This procedure combines model building with a restrained molecular dynamics algorithm, in which distance information from nuclear Overhauser effects is incorporated in the form of pseudo potentials. The method has been applied to the N-terminal DNA-binding domain or headpiece (amino acid residues 1 to 51) of the lac repressor from Escherichia coli, for which no crystal structure is available. The relative orientation of the three helices of the headpiece is similar to that of the three homologous helices found in the cI repressor of bacteriophage lambda.

Spatial arrangement of the three alpha helices in the solution conformation of E. coli lac repressor DNA-binding domain

The relative orientations of the 3 helices in the DNA-binding domain ('headpiece') of lac repressor have been determined using distance constraints obtained from 2-dimensional 1H nuclear Overhauser enhancement spectra. The relative orientations of its helices is similar to that of the central 3 helices in the DNA-binding domain of the lambda repressor of the bacteriophage lambda.

Sequence-specific resonance assignments in the 1H nuclear-magnetic-resonance spectrum of the lac repressor DNA-binding domain 1-51 from Escherichia coli by two-dimensional spectroscopy

The assignment of the 1H nuclear magnetic resonance (NMR) spectrum of the DNA-binding domain 1-51 of lac repressor from Escherichia coli is described and documented. The assignments are based entirely on the amino acid sequence and on two-dimensional NMR experiments at 360 MHz and 500 MHz. Individual assignments were obtained at 18 degrees C for the backbone protons of 44 out of the total of 51 amino acids residues, the exceptions being Met-1, Lys-2, Tyr-7, Arg-35, Glu-36, Lys-37 and Ile-48. Complete assignments of the non-labile hydrogen atoms of the side chain were obtained for 33 residues, and for Asn-46 and Asn-50 the delta amide protons were also identified. The chemical shifts for the assigned resonances at 18 degrees C are listed for an aqueous solution at pH 4.9 and at pH 6.8.

Secondary structure of the lac repressor DNA-binding domain by two-dimensional 1H nuclear magnetic resonance in solution

A recently proposed approach for spatial structure determination in noncrystalline proteins by nuclear magnetic resonance was applied to the lac repressor DNA-binding domain. On the basis of sequence-specific 1H NMR assignments, the location of alpha-helices in the amino acid sequence was determined from nuclear Overhauser enhancement data and from amide proton exchange studies. These investigations provide detailed experimental data on the structure of a noncrystalline DNA-binding protein. The results support the hypothesis advanced by others that sequence-specific interactions between lac repressor and DNA are mediated by a particular spatial arrangement of two alpha-helices common to various different DNA-binding proteins.

Two-dimensional double quantum 1H NMR spectroscopy of proteins

Two-dimensional double quantum 1H NMR spectra are recorded for a protein. The application of this technique to macromolecules is shown not to be impeded by the long preparation pulse sequence essential for this experiment. The identification of spin systems by analysis of the double quantum spectrum is illustrated. Since double quantum spectra do not contain diagonal peaks, connectivities between almost degenerate signals can be detected. By analysis of remote connectivities (i) it can be established whether amide and beta-protons belong to the same spin system or not, (ii) degeneracy of beta-proton chemical shifts can be demonstrated, and (iii) glycine amide protons can be distinguished from all others.

lac Repressor headpiece binds specifically to half of the lac operator: a proton nuclear magnetic resonance study

The complex formation of the N-terminal domain (headpiece) of the Escherichia coli lac repressor and a synthetic 14-base-pair lac operator fragment has been investigated by 1H NMR. Titration shifts in the imino-proton region of the DNA spectrum and in the aromatic region of the headpiece spectrum are examined in detail and interpreted where possible. The assignment of the resonances in the complex follows in part from the titration data and is completed by nuclear Overhauser measurements. The shift of the His-29 C-2 resonance has been used to assess the binding strength of the complex. Evidence is presented for the presence of a high-affinity site on the lac operator fragment (KD less than or equal to 2 X 10(-5) M), which shows features in common with one of the specific binding sites on the complete lac operator, and for the presence of a second, nonspecific binding site with lower affinity. The influence of this second site on the interpretation of the binding data is discussed.

1H NMR studies of lac-operator DNA fragments

The hydrogen-bonded imino protons of a 14 base pair double-stranded DNA fragment comprising one half of the lac operator of E. coli were investigated by 360 MHz H NMR. From combined melting studies of this synthetic 14 b.p. fragment and its two constituent 7 b.p. fragments a nearly complete assignment for the low-field proton resonances was obtained. The experimental spectra are compared with calculated spectra and with the spectrum of a 51 b.p. DNA restriction fragment from E. coli containing the complete lac operator. Structural information on these oligonucleotides is presented. This study is a prerequisite for future 1H NMR investigations of the interaction of the lac operator with the lac repressor.

Equilibrium aspects of the binding of myo-inositol hexakisphosphate to human hemoglobin as studied by 31P NMR and pH-stat techniques

The interaction of myo-inositol hexakisphosphate (P6-inositol) with human hemoglobin has been studied as a function of pH using pH-stat techniques and 31P NMR. With the pH-stat method the following data were obtained: the association constants for the P6-inositol/deoxyhemoglobin and P6-inositol/carboxyhemoglobin complexes at alkaline and acid pH respectively and the proton absorption curves associated with the protein/phosphate interaction for both complexes from pH 5.5 to pH 9. From these data affinities of P6-inositol towards deoxyhemoglobin (Hb) and carboxyhemoglobin (HbCO) have been calculated as a function of pH. The shape of the proton absorption curves was found to be strongly dependent on the ligation state of the hemoglobin molecule. The pH dependence of the 31P NMR spectra of P6-inositol bound to Hb or HbCO provides a monitor for the proton-binding behaviour of the phosphate groups of P6-inositol when present in the central cavity of the protein. It appears that this behaviour is only slightly dependent on the ligation state of the hemoglobin molecule. The NMR spectral data were interpreted in terms of a model which takes into account the electrostatic interaction between the phosphate groups within the P6-inositol molecule as well as the electrostatic interaction between the phosphate groups and positively charged groups on the protein. To account for the discrepancy between the pH-stat and 31P NMR results, i.e. a strong dependence of the proton-absorption curves and a weak dependence of the proton-binding behaviour of P6-inositol on the ligation state of the protein respectively, it is proposed that a conformational change takes place in HbCO upon P6-inositol binding.