A hydrogen-deuterium exchange study of the amide protons of polymyxin B by nuclear-magnetic-resonance spectroscopy.

1. Proton magnetic resonance spectra at 270 MHz of polymyxin B, a cationic oligopeptide antibiotic, show the influence of the inorganic counteranion present in solution. 2. Hydrogen-deuterium exchange rates for the amide protons are of two types, depending on whether the anion is monovalent or polyvalent. Polyvalent anions catalyse the acid-catalysed reaction more than the monovalent anions. 3. The structure in solution was monitored using the proton signals of the amides, the phenylalanine aromatic protons, and the leucine methyl and gamma-CH protons in several polymyxin salts. The temperature coefficients of the chemical shifts of the N-H protons are used to identify two beta turns in the cyclic ring of polymyxin B. The variation in chemical shift of the N-H protons, the aromatic protons and the leucine protons are correlated with anionic size and electronegativity.     

The preferred conformations of protected homodito homoheptamethionine peptides. A1 H n.m.r. study in deuterochloroform medium

Detailed analyses of the conformations of the homo-oligopeptide series, Boc-(L-Met)n-OME n = 2--7, in deuterochloroform have been carried out with proton n.m.r. and IR spectroscopy. Well-resolved high field n.m.r. spectra with assignments for the NH and alpha-CH resonances of these homo-methionine peptides are presented. Extensive n.m.r. concentration-dependent chemical shift studies are combined with IR results to delineate the involvement of the various methionine NH protons in intra- and/or intermolecular hydrogen bonding. N.m.r. chemical shift dependencies with temperature and solvent, DMSO-d6, are used to explore the strength of the hydrogen bonds for the various oligopeptides. At low concentrations, where peptide aggregation is absent, the dipeptide is found to be disordered. The tetra- to heptapeptides possess intramolecular hydrogen bonded seven-membered rings at internal residues. The number of internal rings and the oligopeptide self-association increase with increasing peptide chainlength. At intermediate concentrations associations of peptide molecules with folded structures occur with initial association at the C-terminal region. At high concentrations, "in-register" associated extended beta structures are formed.     

NMR spectroscopy of hydroxyl protons in aqueous solutions of peptides and proteins

Summary Hydroxyl groups of serine and threonine, and to some extent also tyrosine are usually located on or near the surface of proteins. NMR observations of the hydroxyl protons is therefore of interest to support investigations of the protein surface in solution, and knowledge of the hydroxyl NMR lines is indispensable as a reference for studies of protein hydration in solution. In this paper, solvent suppression schemes recently developed for observation of hydration water resonances were used to observe hydroxyl protons of serine, threonine and tyrosine in aqueous solutions of small model peptides and the protein basic pancreatic trypsin inhibitor (BPTI). The chemical shifts of the hydroxyl protons of serine and threonine were found to be between 5.4 and 6.2 ppm, with random-coil shifts at 4°C of 5.92 ppm and 5.88 ppm, respectively, and those of tyrosine between 9.6 and 10.1 ppm, with a random-coil shift of 9.78 ppm. Since these spectral regions are virtually free of other polypeptide¹H NMR signals, cross peaks with the hydroxyl protons are usually well separated even in homonuclear two-dimensional¹H NMR spectra. To illustrate the practical use of hydroxyl proton NMR in polypeptides, the conformations of the side-chain hydroxyl groups in BPTI were characterized by measurements of nuclear Overhauser effects and scalar coupling constants involving the hydroxyl protons. In addition, hydroxyl proton exchange rates were measured as a function of pH, where simple first-order rate processes were observed for both acid- and base-catalysed exchange of all but one of the hydroxyl-bearing residues in BPTI. For the conformations of the individual Ser, Thr and Tyr side chains characterized in the solution structure with the use of hydroxyl proton NMR, both exact coincidence and significant differences relative to the corresponding BPTI crystal structure data were observed.[/p]     

Amine inversion in proteins. A 13C-NMR study of proton exchange and nitrogen inversion rates in N epsilon,N epsilon,N alpha,N alpha-[13C]tetramethyllysine,N epsilon,N epsilon,N alpha,N alpha-[13C]tetramethyllysine methyl ester, and reductively methylated concanavalin A

Exchange rates were calculated as a function of pH from line widths of methylamine resonances in 13C-NMR spectra of N epsilon,N epsilon,N alpha,N alpha-[13C]tetramethyllysine (TML) and N epsilon,N epsilon,N alpha,N alpha-tetramethyllysine methyl ester (TMLME). The pH dependence of the dimethyl alpha-amine exchange rate could be adequately described by assuming base-catalyzed chemical exchange between two diastereotopic methyl populations related by nitrogen inversion. Deprotonation of the alpha-amine was assumed to occur by proton transfer to (1) OH-, (2) water, (3) a deprotonated amine or (4) RCO2-. Microscopic rate constants characterizing each of these transfer processes (k1, k2, k3 and k4, respectively) were determined by fitting the rates calculated from line width analysis to a steady-state kinetic model. Using this procedure it was determined that for both TML and TMLME k2 approximately equal to 1-10 M-1 s-1, k3 approximately equal to 10(6) M-1 s-1 and ki, the rate constant for nitrogen inversion was about 10(8)-10(9) s-1. Upper limits of 10(12) and 10(3) M-1 s-1 could be determined for k1 and k4, respectively. A similar kinetic analysis was used to explain pH-dependent line-broadening effects observed for the N-terminal dimethylalanyl resonance in 13C-NMR spectra of concanavalin A, reductively methylated using 90% [13C]formaldehyde. From exchange data below pH 4 it could be determined that amine inversion was limited by the proton transfer rate to the solvent, with a rate constant estimated at 20 M-1 s-1. Above pH 4, exchange was limited by proton transfer to other titrating groups in the protein structure. Based upon their proximity, the carboxylate side chains of Asp-2 and Asp-218 appear to be likely candidates. The apparent first-order microscopic rate constant characterizing proton transfer to these groups was estimated to be about 1 X 10(4) s-1. Rate constants characterizing nitrogen inversion (ki), proton transfer to OH- (k1) and proton transfer to the solvent (k2) were estimated to be of the same order of magnitude as those determined for the model compounds. On the basis of our results, it is proposed that chemical exchange processes associated with base-catalyzed nitrogen inversion may contribute to 15N or 13C spin-lattice relaxation times in reductively methylated peptides or proteins.     

Effects of N-terminal extension peptides on the structure and stability of bovine pancreatic trypsin inhibitor studied by H n.m.r.

Four N-terminal extended species of the wild-type bovine pancreatic trypsin inhibitor (WT-BPTI), Arg-BPTI (1-BPTI), Met-Glu-Ala-Glu-BPTI (4-BPTI), Ser-Ile-Glu-Gly-Arg-BPTI (5-BPTI) and Gly-Ser-Ile-Glu-Gly-Arg-BPTI (6-BPTI) have been studied by 1H n.m.r. The overall structure of the protein is largely unaffected by the addition of extension peptides. pH titration effects on the C-terminal Ala 58 H beta chemical shift indicate that the structure of 1-BPTI at neutral pH is very similar to that of the WT protein, with a salt bridge between the main chain terminal charges. A salt bridge interaction is prevented by addition of the longer extension peptides. Temperature stabilities are measured by high temperature hydrogen isotope exchange and by microcalorimetry. The stability of 1-BPTI is equal to that of WT-BPTI. A slight decrease in stability is observed for longer extensions, following the order WT-BPTI = 1-BPTI < 5-BPTI = 6-BPTI < 4-BPTI. Small changes in chemical shift are observed for 30 invariant resonances in 4-, 5- and 6-BPTI and for a subset of this group in 1-BPTI. These protons are distributed over about half of the BPTI molecule. The size of the chemical shift changes for many resonances follow the same ranking as the temperature stability. The chemical shift effects are attributed to charge and dielectric effects from extension peptides that probably share a common orientation on the surface of BPTI.     

Preferential location of bulged guanosine internal to a G.C tract by 1H NMR

A series of double-helical oligodeoxyribonucleotides of sequence corresponding to a frame-shift mutational hot spot in the lambda CI gene, 5'-dGATGGGGCAG, are compared by proton magnetic resonance spectroscopy at 500 MHz of the exchangeable protons. Duplexes containing an extra guanine in a run of two, three, and four G.C base pairs are compared to regular helices of the same sequence and to another sequence containing an isolated bulged G, 5'-dGATGGGCAG.dCTGCGCCATC. The imino proton resonances are assigned by one-dimensional nuclear Overhauser effect spectroscopy. Resonances assigned to the G tract in bulge-containing duplexes are shifted anomalously upfield and are very broad. Imino proton lifetimes are determined by T1 inversion-recovery experiments. The exchange rates of G-tract imino protons in bulged duplexes are rapid compared to those in regular helices and are discussed in terms of the apparent rate of solvent exchange for the isolated G bulge. Delocalization of a bulged guanosine in homopolymeric sequences can explain the observed changes in chemical shift and relaxation times across the entire G.C run, and the chemical shifts can be fit by a simple model of fast exchange between base-paired and unpaired states for the imino protons. This allows us to calculate the relative occupancies of each bulge site. In these sequences, we find the extra base prefers positions internal to the G tract over those at the edge.     

The phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus aureus. 3. 1H and 31P nuclear-magnetic-resonance studies on the phosphocarrier protein HPr; tyrosine titration and denaturation studies.

The phosphocarrier protein HPr has been investigated by proton nuclear magnetic resonance (NMR) at 270 MHz in order to evaluate structural properties of the whole molecule and its active site. The titration behaviour of the three tyrosines of the HPr protein was analysed by monitoring the chemical shifts of the aromatic proton resonances of these residues as a function of pH. It was found that the HPr protein contains a lot of slowly exchanging NH backbone protons which suggested a relatively rigid secondary structure of the protein molecule itself although it contains no disulfide bridges. The HPr protein shows a sharp reversible denaturation behaviour at alkaline pH values. Between pH 10.8 and 11.1 two C-2 proton resonance peaks for the single histidine residue could be observed together with abrupt changes in the aromatic and aliphatic absorption region of the HPr protein which are due to chemical exchange processes. The NMR spectrum of the HPr protein is only changed a little upon raising the temperature from 14 degrees C to 70 degrees C. At 76 degrees C all resonances in the spectrum broaden and almost disappear. This process is irreversible.     

Investigation of the relationship between tyrosyl residues and the adenosine 5'-monophosphate binding site of rabbit liver fructose-1,6-biphosphatase as studied by chemical modification and nuclear magnetic resonance spectroscopy

The effects of AMP, fructose 6-phosphate (Fru-6-P), fructose 2,6-bisphosphate (Fru-2,6-P2), and paramagnetic ions on the aromatic region of the proton nuclear magnetic resonance (NMR) spectrum of rabbit liver fructose-1,6-bisphosphatase have been investigated at 300 MHz. Two well resolved peaks in this region of the NMR spectrum are assigned to the protons from the aromatic ring of a tyrosyl residue of the enzyme by chemical modification with tetranitromethane and by nuclear Overhauser effects. Nitration of the tyrosyl residue causes desensitization of the enzyme to AMP inhibition as well as the loss of activity. In the presence of AMP during the modifications, 1 tyrosyl residue could be protected, presumably the one observed by NMR. Binding of AMP, an allosteric inhibitor of the enzyme, to rabbit liver fructose-1,6-bisphosphatase leads to an upfield shift of the tyrosyl proton signals in the NMR spectrum. No chemical shift or line broadening could be detected in the presence of the paramagnetic manganous ion, Fru-2,6-P2, or Fru-6-P. The negative intramolecular nuclear Overhauser effect from the ribose H2' proton to the adenine H8 proton of AMP suggested that AMP binds to the enzyme with an anti conformation about the glycosidic bond. The failure to observe intermolecular nuclear Overhauser effects between the tyrosyl residue and the protons of AMP indicates that the distances between them are greater than 4 A. On the basis of these observations, it is suggested that the AMP-related tyrosyl residue may be close to the AMP binding site, but it is not directly involved in ligand binding. Rather, the protection of this tyrosyl residue by AMP as observed by chemical modification experiments may well be due to a conformational change that results from covalent modification of the enzyme.     

A complete proton and carbon-13 NMR analysis of fluocinonide, a fluorinated corticosteroid

This paper presents a complete analysis of the proton and carbon-13 NMR spectra of 21-acetoxy-6 alpha,9-difluoro-11 beta-hydroxy-16 alpha,17-(1-methylethylidene) bis-(oxy) pregna-1,4-diene-3,20-dione, a potent anti-inflammatory fluorosteroid. The 300 MHz proton spectrum was analyzed using a combination of the two-dimensional homonuclear chemical shift correlation (COSY) technique and one-dimensional NOE difference spectra. Exact coupling constants and chemical shifts were obtained by spectral simulation and iteration. The carbon-13 spectrum was assigned from the proton spectrum via a two-dimensional heteronuclear chemical shift experiment, and long-range fluorine-proton couplings were confirmed by a fully coupled heteronuclear COSY-type experiment.     

1H NMR (500 MHz) of gene 32 protein--oligonucleotide complexes

In concentrated solutions, gene 32 single-stranded DNA binding protein from bacteriophage T4 (gene 32P) forms oligomers with long rotational correlation times, rendering 1H NMR signals from most of the protons too broad to be detected. Small flexible N- and C-terminal domains are present, however, the protons of which give rise to sharp resonances. If the C-terminal A domain (48 residues) and the N-terminal B domain (21 residues) are removed, the resultant core protein of 232 residues (gene 32P) retains high affinity for ssDNA and remains a monomer in concentrated solution, and most of the proton resonances of the core protein can now be observed. Proton NMR spectra (500 MHz) of gene 32P and its complexes with ApA, d(pA)n (n = 2, 4, 6, 8, and 10), and d(pT)8 show that the resonances of a group of aromatic protons shift upfield upon oligonucleotide binding. Proton difference spectra show that the 1H resonances of at least one Phe, one Trp, and five Tyr residues are involved in the chemical shift changes observed with nucleotide binding. The number of aromatic protons involved and the magnitude of the shifts change with the length of the oligonucleotide until the shifts are only slightly different between the complexes with d(pA)8 and d(pA)10, suggesting that the binding groove accommodates approximately eight nucleotide bases. Many of the aromatic proton NMR shifts observed on oligonucleotide complex formation are similar to those observed for oligonucleotide complex formation with gene 5P of bacteriophage fd, although more aromatic residues are involved in the case of gene 32P.(ABSTRACT TRUNCATED AT 250 WORDS)     

Rapid amide proton exchange rates in peptides and proteins measured by solvent quenching and two-dimensional NMR.

In an effort to develop a more versatile quenched hydrogen exchange method for studies of peptide conformation and protein-ligand interactions, the mechanism of amide proton exchange for model peptides in DMSO-D2O mixtures was investigated by NMR methods. As in water, H-D exchange rates in the presence of 90% or 95% DMSO exhibit characteristic acid- and base-catalyzed processes and negligible water catalysis. However, the base-catalyzed rate is suppressed by as much as four orders of magnitude in 95% DMSO. As a result, the pH at which the exchange rate goes through a minimum is shifted up by about two pH units and the minimum exchange rate is approximately 100-fold reduced relative to that in D2O. The solvent-dependent decrease in base-catalyzed exchange rates can be attributed primarily to a large increase in pKa values for the NH group, whereas solvent effects on pKW seem less important. Addition of toluene and cyclohexane resulted in improved proton NMR chemical shift dispersion. The dramatic reduction in exchange rates observed in the solvent mixture at optimal pH makes it possible to apply 2D NMR for NH exchange measurements on peptides under conditions where rates are too rapid for direct NMR analysis. To test this solvent-quenching method, melittin was exchanged in D2O (pH 3.2, 12 degrees C), aliquots were quenched by rapid freezing, lyophilized, and dissolved in quenching buffer (70% DMSO, 25% toluene, 4% D2O, 1% cyclohexane, 75 mM dichloroacetic acid) for NMR analysis. Exchange rates for 21 amide protons were measured by recording 2D NMR spectra on a series of samples quenched at different times. The results are consistent with a monomeric unfolded conformation of melittin at acidic pH. The ability to trap labile protons by solvent quenching makes it possible to extend amide protection studies to peptide ligands or labile protons on the surface of a protein involved in macromolecular interactions.     

5,6,7,8-Tetrahydrofolic acid. Conformation of the tetrahydropyrazine ring

It is suggested from analysis of proton spin-spin coupling constants that the tetrahydropyrazine ring of tetrahydrofolate is a roughly equal mixture of two half-chair conformations, one with the C-6 proton axial and the other with the C-6 proton equatorial. The chemical shifts and spin-spin coupling constants for the carbon-bound protons of (+/-)-L-, (-)-L-, and (-)-L-[6-2H] 5,6,7,8-tetrahydrofolate were measured at 25 degrees and at 300 MHZ. The resonances corresponding to the two C-7 protons in the deuterated compound constituted an AB quartet with JAB of 12 Hz and chemical shift difference of 92 Hz or 0.307 ppm; the C-7 protons are proposed to be a geminally coupled axial-equatorial pair whose rapid equilibration does not result in equivalence due to the adjacent chiral center at C-6. The spin-spin splitting in the C-7 resonances were 3.0 and 6.6 Hz for the low field and high field resonances, respectively, reflecting coupling to the C-6 proton. These coupling constants reflect the conformational equilibrium. The resonances assignable to C-9 protons are nearly equivalent in the 6-2H compound, but exhibit the resonances corresponding to a complex spin system in the 6-H compound.     

Application of peptide-mediated ring current shifts to the study of neurophysin-peptide interactions: a partial model of the neurophysin-peptide complex

Perdeuteriated peptides were synthesized that are capable of binding to the hormone binding site of neurophysin but that differ in the position of aromatic residues. The binding of these peptides to bovine neurophysin I and its des-1-8 derivative was studied by proton nuclear magnetic resonance spectroscopy in order to identify protein residues near the binding site through the observation of differential ring current effects on assignable protein resonances. Phenylalanine in position 3 of bound peptides was shown to induce significant ring current shifts in several resonances assignable to the 1-8 sequence, including those of Leu-3 and/or Leu-5, but was without effect on Tyr-49 ring protons. The magnitude of these shifts was dependent on the identity of peptide residue 1. By contrast, the sole demonstrable direct effect of an aromatic residue in position 1 was a downfield shift in Tyr-49 ring protons. Study of peptide binding to des-1-8-neurophysin demonstrated similar conformations of native and des-1-8 complexes except for the environment of Tyr-49, confirmed the peptide-induced ring current shift assignments in native neurophysin, and indicated an effect of binding on Thr-9. These observations are integrated with other results to provide a partial model of neurophysin-peptide complexes that places the ring of Tyr-49 at a distance 5-10 A from residue 1 of bound peptide and that places both the 1-8 sequence and the protein backbone region containing Tyr-49 proximal to each other and to peptide residue 3.(ABSTRACT TRUNCATED AT 250 WORDS)     

A 500 MHz proton NMR study of interaction of tripeptides Lys-Tyr-Lys and Lys-Phe-Lys with deoxydinucleotide d-CpG.

The binding of di- and tetranucleotides with tri- and tetrapeptides containing Tyr, Trp, Phe having lysine on both ends has been studied using a 500 MHz proton NMR. The results show that d-CpG exists as a right-handed B-DNA structure with both sugars in 01'-endo sugar conformation and glycosidic bond angle as in anti domain. On binding to tripeptide Lys-Tyr-Lys, the Tyr ring protons shift upfield by 0.015 ppm at 285 degrees K, while the conformation of d-CpG remains unchanged. Change in chemical shift of Tyr and nucleotide protons decreases with temperature. This upfield shift is attributed to stacking with bases/base-pairs. The presence of intermolecular NOE's also supports this. Results of binding of d-CpG to Lys-Phe-Lys are similar to those with Lys-Tyr-Lys except that the chemical shift changes occur to a lesser extent. On comparing the results obtained with three different peptides, it is found that interaction decreases in the order Trp > Tyr > Phe which is similar to that found by theoretical energy calculations (reported elsewhere) and fluorescence measurements. The results also exhibit a specificity in recognition of these amino acid residues by dinucleotides.     

Hydrogen kinetics of peptide amide protons at the bovine pancreatic trypsin inhibitor protein-solvent interface

Hydrogen exchange rate constants of the 25 most rapidly exchanging peptide amide protons in bovine pancreatic trypsin inhibitor have been determined over a range of pH that spans pH min, the pH of minimum rate. Most of these are on the protein surface, exposed to solvent and not hydrogen bonded in the crystal structure. Contrary to commonly held assumptions, the exchange kinetics of surface NH groups are not equivalent to the kinetics of NH groups in peptides in the extended configuration. All surface NH groups exchange more slowly than NH groups in model peptides, with rate constants distributed over a range of more than two orders of magnitude. In addition, their pH min values vary widely. For most of the surface NH groups, pH min is lower than in model compounds and, for several, pH min is less than 1. These results indicate that the local environment of the surface peptide groups when the exchange event occurs is very different from that of extended peptides. Analysis based on consideration of an O-protonation mechanism for acid catalysis and of electrostatic effects on exchange kinetics further indicates (see the accompanying paper) that, in general, exchange of surface NH groups occurs from a conformation of the protein approximated by the crystal structure. The 1H-2H exchange rate constants were measured from 300 MHz nuclear magnetic resonance spectra in which assigned surface N1H resonances are resolved by the use of partially deuterated protein samples. A marked pH dependence of the chemical shifts observed in the pH range 1 to 4.5 for several surface NH groups reflects the titration of nearby carboxyl groups.     

A preliminary CD and NMR study of the Escherichia coli DNA polymerase III theta subunit.

The theta subunit of DNA polymerase III, the main replicative polymerase of Escherichia coli, has been examined by circular dichroism and by NMR spectroscopy. The polymerase core consists of three subunits: alpha, epsilon, and theta, with alpha possessing the polymerase activity, epsilon functioning as a proofreading exonuclease, and theta, a small subunit of 8.9 kD, of undetermined function. The theta subunit has been expressed in E. coli, and a CD analysis of theta indicates the presence of a significant amount of secondary structure: approximately 52% alpha helix, 9% beta sheet, 21% turns, and 18% random coil. However, at higher concentrations, theta yields a poorly-resolved 1D proton NMR spectrum in which both the amide protons and the methyl protons show poor chemical shift dispersion. Subsequent 1H-15N HSQC analysis of uniformly-15N-labeled theta supports the conclusion that approximately half of the protein is reasonably well-structured. Another quarter of the protein, probably including some of the N-terminal region, is highly mobile, exhibiting a chemical shift pattern indicative of random coil structure. The remaining amide resonances exhibit significant broadening, indicative of intermolecular and/or intramolecular exchange processes. Improved chemical shift dispersion and greater uniformity of resonance intensities in the 1H-15N HSQC spectra resulted when [U-15N]-theta was examined in the presence of epsilon186--the N-terminal domain of the epsilon-subunit. Further work is currently in progress to define the solution structure of theta and the theta-epsilon186 complex.     

NMR studies of defensin antimicrobial peptides. 1. Resonance assignment and secondary structure determination of rabbit NP-2 and human HNP-1.

Two-dimensional nuclear magnetic resonance spectroscopy has been used to make resonance assignments of the proton spectra of two defensin antimicrobial peptides, human neutrophil peptide HNP-1 and rabbit neutrophil peptide NP-2. The secondary structures of these peptides were determined from analysis of the proton-proton NOEs and from the positions of slowly exchanging amide protons. Both peptides contain a long stretch of a double-stranded antiparallel beta-sheet in a hairpin conformation that contains a beta-bulge, a short region of triple-stranded beta-sheet, and several tight turns. The NMR results clearly show that HNP-1 forms a dimer or higher order aggregate in solution and that Pro8 exists as a cis peptide bond. The NMR data on these peptides are compared with NMR data for a homologous peptide NP-5 [Bach, A. C., Selsted, M. E., & Pardi, A. (1987) Biochemistry 26, 4389-4397]. Analysis of the conformation-dependent proton chemical shifts shows that it is not possible to confidently judge the structural similarity of the three defensins from chemical shift data alone. However, comparison of the 3JHN alpha coupling constants in NP-2 and NP-5 indicates that the backbone conformations for these peptides are very similar. A more detailed comparison of the solution conformations of the defensins peptides is made in the following paper in this issue where the NMR data are used as input for distance geometry and molecular dynamics calculations to determine the three-dimensional structures of HNP-1 and NP-2.     

Conformations of cyclic peptides. V. A proton magnetic resonance study of evolidine, cyclo-ser-phe-leu-pro-val-asn-leu

The 220 MHz proton magnetic resonance spectrum of the cyclic heptapeptide evoli-dine, cyclo-Ser-Phe-Leu-Pro-Val-Asn-Leu, has been analyzed. From the temperature dependence of chemical shift of the peptide protons in dimethyl sulfoxide, it is concluded that the peptide protons of the Asn and Phe residues are shielded from the solvent. This observation and H-C_α-N-H dihedral angles, estimated from the corresponding coupling constants, are combined in a proposed conformation of the peptide backbone. The consistency of this conformation with other proton magnetic resonance observations is discussed.     

1H-N.m.r. spectral assignments for two series of heparin-derived oligosaccharides.

Six heparin-derived oligosaccharides, ranging in size from di- to octa-saccharide and forming two closely related series differing in structure by the substitution of an unsulfated D-glucuronate for a 2-sulfated L-iduronate residue, have been characterized by 2-dimensional 1H-n.m.r. spectroscopy. In addition to providing new data on hexa- and octa-saccharides, several important changes to previously published data have been found for the two tetrasaccharides. The D-glucuronic acid H-5 proton is assigned to a resonance in the same region as resonances for the H-3 and H-4 D-glucuronate protons, rather than downfield from these resonances as earlier reported. The presence of D-glucuronic acid in the heparin sequence of the series-1 fragments affects the positions of neighboring D-glucosamine resonances, in particular shifting the anomeric proton signal in the preceding D-glucosamine 0.1-0.2 p.p.m. downfield. Resonances from the reducing-end D-glucosamines differ from internal D-glucosamine resonances both in relative position and in the degree of chemical shift difference between the H-6 and H-6' protons. This work illustrates the usefulness of two-dimensional techniques in determining heparin structure and emphasizes the need for direct analysis, rather than assignment by comparison to model compounds.     

Epidermal growth factor from the mouse. Physical evidence for a tiered beta-sheet domain: two-dimensional NMR correlated spectroscopy and nuclear Overhauser experiments on backbone amide protons

When H2O-exchanged, lyophilized mouse epidermal growth factor (mEGF) is dissolved in deuterium oxide at low pH (i.e., below approximately 6.0), 13 well-resolved, amide proton resonances are observed in the downfield region of an NMR spectrum (500 MHz). Under the conditions of these experiments, the lifetimes of these amide protons in exchange for deuterons of the deuterium oxide solvent suggest that these amide protons are hydrogen-bonded, backbone amide protons. Several of these amide proton resonances show splittings (i.e., JNH alpha-CH) of approximately 8-10 Hz, indicating that their associated amide protons are in some type of beta-structure. Selective nuclear Overhauser effect (NOE) experiments performed on all amide proton resonances strongly suggest that all 13 of these backbone amide protons are part of a single-tiered beta-sheet structural domain in mEGF. Correlation of 2D NMR correlated spectroscopy data, identifying scaler coupled protons, with NOE data, identifying protons close to the irradiated amide protons, allows tentative assignment of some resonances in the NOE difference spectra to specific amino acid residues. These data allow a partial structural model of the tiered beta-sheet domain in mEGF to be postulated.