Hysteretic kinetic behavior of beef liver pyruvate carboxylase.

Natural abundance ¹³C nuclear magnetic resonance (nmr) spectra have been obtained for samples of a variety of native collagens by use of cross-polarization (CP) techniques which permit high resolution natural abundance ¹³C nmr spectra of solids to be obtained with high sensitivity. The CP ¹³C nmr spectra of lyophilized skin and tendon collagens consisted of two broad resonance envelopes spanning a five kHz range. Hydrated tendon collagen gave rise to a CP spectrum very similar to that obtained for the lyophilized sample, indicating that it retains its solid-like properties. In contrast, hydrated skin collagen became denatured under the conditions of the CP experiment and subsequently gave rise to a conventional high-resolution Fourier transform (FT) nmr spectrum. The CP ¹³C nmr spectrum of ivory was similar to those of lyophilized skin and tendon collagens, demonstrating the solid-like character of the collagen in dentine, whereas the CP spectrum of bovine nasal cartilage reflected the presence of highly mobile proteoglycan components in addition to relatively rigid collagen molecules. In the case of ivory, the resolution of the CP spectrum was enhanced by “magic angle” spinning to a degree approaching that of conventional FT ¹³C nmr spectra of denatured collagen in solution. Because of its ability to probe the dynamic properties of solid-like biological molecules, CP ¹³C nmr spectroscopy should be a valuable investigative tool for future studies.     

A 13C nmr and esr study on the structure of the different forms of the cobalt-bleomycin A2 complex

¹³C nmr and esr spectra have been recorded from oxygenated cobalt-bleomycin A₂. It appears that (a) in oxygenated cobalt-bleomycin all the cobalt is in the Co³⁺ oxidation state, (b) the ¹³C nmr data indicate a structure of the Co-bleomycin complex in which the nitrogens of the pyrimidine, the imidazole, and the secondary and primary amine of the diaminopropanoic amide are involved as planar equatorial ligands, and (c) free bleomycin forms a “dimer” with Co-bleomycin.     

Properties of metal-ion coordinated imidazoles: nmr and C-2 H Exchange in Co(III) Complexes

The ¹H and ¹³C nmr spectra of Co(NH₃)₅ImH³⁺ and the ¹H nmr spectra of αCotrien(ImH)₂³⁺ and βCotrien(ImH)₂³⁺ are reported. The pK_a values determined from the dependence of the chemical shift on pH are 10.0, 9.6, and 10.1, respectively. The range of the chemical shift between the acid and base forms is unusually small in the ¹H nmr, 0.5–0.7 ppm for the C-2 H and about 0.25 ppm for the C-4 H and C-5 H. In the ¹³C nmr, C-2 and C-4 have large shifts to low field and C-5 a small shift to high field on deprotonation. The C-2 proton is not exchanged with solvent ²H under acidic or basic conditions, in marked contrast to the corresponding proton in both imidazole and 1-methylimidazole. These spectroscopic and chemical properties should be useful for the direct identification of metal-ion coordinated histidines in proteins.     

Carbon-13 nuclear magnetic resonance spectral analysis of C-nucleosides. The structure of pyrazomycin B 1

The ¹³C nmr spectra of three nucleosides and four C-nucleosides have been recorded and all carbon signals assigned. These data have been utilized for the determination of the structure and conformation of the antibiotic pyrazomycin B. Steric differences have been shown to be reflected in the chemical shift values.     

CD and nmr studies on the interaction of lithium ion with valinomycin and gramicidin-S

The conformation of the valinomycin–lithium complex has been studied using CD and nmr techniques. The lithium ion induced significant changes in the chemical shifts of the NH and C^αH protons, as well as in the CD spectra of valinomycin. From the analysis of the lithium ion titration data, it is concluded that valinomycin forms a 1:1 type weak complex with lithium, having a stability constant of 48 L mol^?1 at 25°C. This conformation is different from the familiar valinomycin–potassium complex. The nature of the interaction at low and high concentrations of lithium ions with valinomycin (ionophore) and gramicidin-S (nonionophore) has been compared. At high salt concentrations, there was a further change in the CD and nmr spectra of valinomycin, giving a second plateau region at > 3M of the salt. In the case of gramicidin-S, no significant changes in the nmr or CD spectra were observed in the lower concentration range corresponding to where changes were observed in the case of valinomycin. However, the addition of lithium salt at concentrations greater than 3M induced changes in both the CD and nmr spectra of gramicidin-S, and the titration graph of molar ellipticity versus concentration of lithium perchlorate gave a plateau region at concentrations greater than this. These results indicate that the effects of lithium at low and high concentrations are independent of each other. The conformational transitions at very high salt concentrations (denaturation) are more likely due to solvent structural perturbations rather than to the consequences of ion binding.     

Conformational analysis of dolastatin 10: An nmr and theoretical approach

A solution conformational analysis of dolastatin 10, a powerful antineoplaslic agent, has been carried out by means of nmr techniques and theoretical calculations. ¹H mono- and bidimensional nmr experiments, as well as ¹H-¹³C heterocorrelated spectra, have been performed on CD₂Cl₁₂ solutions. The most interesting nmr data is a huge shielding of the aCH (25) proton of the Dov residue, suggesting the presence of an interaction between the N-terminal and the aromatic C-terminal ends of the molecule. The possibility of a head-to-tail intermolecular association having been discarded, the presence of a series of preferred folded conformation has been hypothesized. Conformational theoretical analysis supports the nmr hypothesis of a folded peptide-like molecule, and a series of possible conformers in good agreement with the experimental data have been analyzed. © 1995 John Wiley & Sons, Inc.     

Effects of molecular association on structure and dynamics of a collagenous peptide

Peptide GVKGDKGNPGWPGAPY from the triple-helix domain of type IV collagen aggregates in solution at a critical aggregation concentration of 18 mM. This molecular self association process is investigated by ¹H- and ¹³C-nmr spectroscopy. As a function of increasing peptide concentration, selective ¹H resonances are cooperatively chemically shifted by up to 0.04 ppm to apparently saturable values at high concentration. Pulsed field gradient nmr was used to derive translation diffusion constants that, as the peptide concentration is increased, also cooperatively and monotonically decrease to an apparent limiting value. An average number of 6 monomer units per aggregate have been estimated from diffusion constant and ¹³C relaxation data. Comparative ¹H nuclear Overhauser effect spectroscopy (NOESY) spectra accumulated at high and low peptide concentrations suggest that average internuclear distances are decreased as a result of peptide association. ¹³C-nmr multiplet spin-lattice relaxation and ¹³C- {¹H} NOE effects on ¹³C-enriched glycine methylene positions in the peptide demonstrate that overall molecular tumbling and backbone internal motions are attenuated in the aggregate state. Lowering the solution pD from pD 6 to pD 2 disrupts the aggregate state, suggesting a role for electrostatic interactions in the association process. Based on thermodynamic considerations, hydrophobic interactions also probably act to stabilize the aggregate state. These data are discussed in terms of an nmr/NOE constrained computer-modeled structure of the peptide. © 1993 John Wiley & Sons, Inc.     

Cross-polarization NMR of N-15 labeled soybeans

Cross-polarization ¹⁵N nmr spectra of ¹⁵N-labeled soybean seeds, pods, and leaves have been obtained at 9.12 MHz both with and without high-speed sample rotation at the magic angle. Spectral resolution is sufficient to permit a determination of the relative concentrations of amide and amine nitrogens, as well as of a few specific amino acid residues of proteins in the solid, intact samples. Utilization by soybean of nitrogen from labeled fertilizer in the presence of dinitrogen fixation can be determined from these spectra. A double-cross polarization ¹³C nmr spectrum of a spinning, ¹⁵N-labeled seed has been obtained in which resonances are observed only from these carbons directly bonded to nitrogens. This technique leads to a qualitative estimate of amino-acid composition of the protein which is complementary to that obtained directly from the ¹⁵N nmr spectrum.     

A 13C nuclear magnetic resonance study of the interaction of ligands with arginine residues in dihydrofolate reductase.

¹³C nmr spectra of $\text{Streptococcus faecium}$ dihydrofolate reductase containing [¹³C-guanidino] arginine and ligand complexes with the labeled enzyme are reported. The spectrum of the native enzyme shows 5 well-resolved resonances (the enzyme contains 8 Arg) with a chemical shift range of 1.2 ppm. Addition of ligands to the enzyme produces distinct changes in the enzyme spectrum, and demonstrates that ¹³C nmr of labeled protein can be used in studies of protein-ligand interactions. An example of the use of ¹³C-depleted material is also presented.     

Measurement of long-range2 13C-1H coupling constants of 95% uniformly 13C-labeled polysaccharide from streptococcus mitis J22

The coaggregation of Streptococcus mitis strain J22 in the early stages of dental plaque formation has been shown to result from interaction of cell wall polysaccharides with lectins on the surface of other oral bacterial species. This bacterium was grown in a medium containing ¹³C as the sole carbon source. We have isolated the lectin receptor polysaccharide from this strain with full enrichment in ¹³C and have determined a number of two-bond and three-bond ¹³C-¹H coupling constants from measurements of the offsets in two-dimensional homonuclear nmr spectra [exclusive correlated spectroscopy (E-COSY) method]. A scheme for reliable extraction of these coupling constants from homonuclear Hartmann-Hahn and nuclear Overhauser effect spectroscopy spectra is tested in model compounds. We interpret the three-bond coupling across the glycosidic linkage in terms of dihedral angles in order to provide conformational information to supplement molecular modeling and nuclear Overhauser effect data. We show that the E-COSY method works well even for coupling constants smaller than the nmr line width and that a number of the ³J_CH across the glycosidic linkage are in the range of 1–2 Hz, which is much smaller than many previously reported values. © 1994 John Wiley & Sons, Inc.     

Mono and two-dimensional 500-MHz characterization of synthetic bombesin and related peptides in DMSO and DMSO-water

The proton nmr characterization of bombesin (BBS) and of two peptide fragments corresponding to the (1-6) and (6-14) sequences has been carried out at 500 MHz in dimethyl sulfoxide (DMSO-d6) using two-dimensional (2D) homo and 1H-13C heterocorrelated techniques. All resonances in the nmr spectra have been assigned and several coupling constants have been measured. The backbone J alpha CH-NH coupling constants are quite similar and around 7.8-8.2 Hz, pointing to an unfolded structure in DMSO-d6. The possibility of secondary structures in highly viscous mixtures of DMSO-d6-water was investigated. The existence of sequential nuclear Overhauser enhancement (NOE) effects in the C-terminal nonapeptide section may indicate a preferential site for secondary structuring.     

The X-Pro peptide bond as an nmr probe for conformational studies of flexible linear peptides

The equilibrium between the cis and trans forms of X-Pro peptide bonds can readily be measured in the ¹³C nmr spectra. In the present paper we investigate how observation of this equilibrium could be used as an nmr probe for conformational studies of flexible polypeptide chains. The experiments include studies by ¹³C nmr of a series of linear oligopeptides containing different X-L -Pro peptide bonds, with X = Gly, L -Ala, L -Leu, L -Phe, D -Ala, D -Leu, and D -Phe. Overall the study confirms that X-Pro peptide bonds can generally be useful as ¹³C nmr probes reporting the formation of nonrandom conformation in flexible polypeptide chains. It was found that the cis–trans equilibrium of X-Pro is greatly affected by the side chain of X and the configuration of the α-carbon atom of X. On the basis of these observations some general rules are suggested for a practical applications of the X-Pro nmr probes in conformational studies of polypeptide chains.     

Synthesis of linear stereoregular glucomannan heteropolysaccharides

A series of stereoregular α-(1 → 6) linked glucomannans have been prepared by Lewis acid-catalyzed copolymerization of anhydro sugar derivatives followed by debenzylation. The products have been characterized for mole fraction of the individual monomer, and sequence lengths have been calculated from copolymerization data. The viscosity, specific rotation, and ¹³C nmr spectra have been correlated with the structure of the various copolymers.     

A nuclear magnetic resonance study of the helix–coil transition of poly(L-glutamic acid)

There have been many reports that the nuclear magnetic resonance (nmr) spectra of a large number of polypeptides exhibit peak doubling of the α-carbon and the α-carbon proton in the helix–coil transition region. One apparent exception to this generalization has been polypeptides with ionizable side chains, where the helix–coil transition is induced by changes in pH in aqueous solution. Because it is important to establish the proper theoretical reason for the peak doubling and its relation to the rate of conformational change of amino acid residues, we have reexamined the proton and carbon-13 nmr spectra, at high field, for two polydisperse samples of poly(L -glutamic acid). Doubling of the α-carbon proton resonance as well as those of the α- and β-carbon, and backbone carbonyl are observed for a low-molecular-weight sample (DP = 54), while a higher molecular weight sample (DP = 309), exhibits only single resonances. Thus, polydispersity by itself is not sufficient to observe peak doubling; low-molecular weight is also required.     

Metabolism of progesterone and testosterone by a Bacillus sp.

Microbial transformations by a Bacillus sp. were employed as a means of preparing potentially important derivatives of progesterone and testosterone. Each microbial metabolite was subjected to structure elucidation employing ¹H and ¹³C nmr, mass spectral and cd analysis. Hplc was used for the determination of the percentages of the metabolites formed. The progesterone metabolites were characterised as 14-hydroxy-4-pregnene-3,20-dione (II), 14-hydroxy-5 α -pregnane-3,6,20-trione (III)., 11 α — hydroxy-5 α — pregnane-3, 6,20-trione (IV) and 11 α, 14-dihydroxy-4-pregnene-3,20-dione (V). The testosterone analogs were identified as 4-androstene-3,17-dione (VII), 17 β-hydroxy-5 α -androstene-3,6-dione (VIII), 14-hydroxy-4-androstene-3,17-dione (IX) and 14, 17 β-dihydroxy-4-androsten -3-one (X)₁. The availability of the metabolites enabled complete elucidation of their ¹³C nmr spectra.     

13C nmr studies of aurothioglucose: Ligand exchange and redox disproportionation reactions

¹³C nmr studies of gold thioglucose, AuSTg, and solutions containing added β-1-D-thioglucose, TgSH, have been conducted at PD 7.4 and interpreted in terms of complexation and ligand exchange reactions that are consistent with the known preference of gold(I) for linear two-coordinate structures. The upper limit of the half-life for ligand exchange between 0.25 M Au(STg)₂^? and TgSH at pD 7.4 is 2.2 msec. The ¹³C nmr spectra of various thioglucose derivatives have been assigned. A novel oxidation reduction reaction was discovered that leads to the formation of metallic gold and a product tentatively identified as the sulfinic acid derivative of thioglucose. The presence of sulfinic acid in AuSTg was indicated by the infrared absorption at 1050 cm^?1. The same product was formed by slow hydrolysis of thioglucose disulfide. A mechanism for the formation of the sulfinic acid derivative from AuSTg is proposed.     

Comparison of the effects of calcium and magnesium on the conformation of tetra cycline in Me2SO solution

The effects of anhydrous Ca(NO₃)₂ on the ¹³C nuclear magnetic resonance (nmr) and circular dichroism spectra of tetracycline in Me₂SO-d₆ solution have been investigated in order to make a comparison with the results of a previous study in which the effects of Mg(NO₃)₂ were determined under the same conditions. The results of experiments described in this article provide strong evidence that Ca²⁺ and Mg²⁺ bind tetracycline at the same sites in Me₂SO and that both ions induce the same change in molecular conformation of tetracycline upon binding. The Ca²⁺ complex, in contrast to the Mg²⁺ complex, has a lifetime that is short on the nmr time scale.     

Conformer equilibria of triostin A and its conformer-specific interaction with nucleic acid bases

A quinoxaline antibiotic triostin A has a bicyclic octadepsipeptide structure. Proton and carbon-13 nmr spectra showed the presence of two symmetrical conformations favoring polar and nonpolar solvents, respectively. They interconvert slowly on the nmr time scale, and this slow interconversion is due to the cooperative effects of the presence of the quinoxaline ring and the N-methyl peptide bonds. Reversal of the chirality of the disulfide bond as the origin of the slow exchange was excluded by the presence of two conformers for S-benzyltriostin A. Conformer 2, which favors the polar solvent, can form hydrogen-bonded complexes with purine nucleoside derivatives in organic solvents, but conformer 1 does not. The binding sites were elucidated and a mode of interaction with DNA proposed.     

On the double peak of NMR in the helix—coil transition region

To attempt to resolve the controversy over “fast” and “slow” helix–coil transition rates in polypeptides, nuclear magnetic resonance spectra were measured for monodisperse poly-γ-benzyl-L -glutamate (PBLG). These results were compared with simulated line spectra which were computed by taking the molecular-weight distribution into consideration. Broad but single peaks have been observed in 220 mHz nmr for the α-CH and NH proton resonance spectra in the transition region. The shape of the line changes with the extent of polydispersity. Assuming a fast conversion rate, a molecular model of the helix–coil transition simulates these results. Consequently, the double peak which has been observed in the nmr of polypeptides at the helix–coil transition region is shown to result from the polydispersity in molecular weight.