Partial characterization of dermatan sulfate by proton nuclear magnetic resonance spectroscopy

The degree of galactosamine N-acetylation, iduronic acid composition, and total uronic acid/hexosamine ratios of the three dermatan sulfates of human skin, DS18, DS28, and DS35 (M. O. Longas et al. (1987) Carbohydr. Res. 159, 127-136), were determined by Fourier transform, proton nuclear magnetic resonance (FT 1H NMR) spectroscopy. Analysis of DS of varying ages was conducted at 400 MHz and 60 degrees C. Chemical shifts for H-1, H-2, H-4, and H-5 of L-IdUA were independent of those for the respective protons of D-GalNAc and D-GlcUA. The resonance intensities of H-1 and acetamido methyl protons of D-GalNac did not display the expected 1:3 ratios. Therefore, their integration values were employed to estimate the percentage N-acetylation (N-CH3/3 H-1) which was corroborated chemically. The L-IdUA content, relative to total uronic acid, was calculated from signal intensities of H-1 of L-IdUA and D-GlcUA and ascertained by quantitative chemical methods. Total uronic acid/hexosamine ratios were determined from both 1H NMR spectroscopy and chemical analyses. The data show the following N-acetylation (N-CH3/3 H-1) of galactosamine in DS:DS18, 61-72% between 17 and 60 years, unaffected by senescence; DS28, 78-86% with no age-related trend; DS35, 101% at 19 years. Furthermore, in all ages investigated, the percentage (wt/wt) L-IdUA relative to total uronic acid was 42-44% for DS18 and 37-40% for DS28. At age 19 years, DS35 had a 29% (wt/wt) L-IdUA. The total uronic acid/hexosamine ratios for DS18 and DS28 varied from 1.40:1.0 to 1.70:1.0 irrespective of age.     

Conformational analysis by nuclear magnetic resonance: insulin

High-resolution 270-MHz proton nuclear magnetic resonance (NMR) spectra of the native two-zinc insulin hexamer at pH 9 have been obtained, and assignments of key resonances have been made. Spectra of zinc-free insulin titrated with Zn2+ are unchanged after the addition of 1 equiv of zinc per insulin hexamer, indicating that the conformation of the hexamer is fixed at this point and that the second zinc ion does not significantly change the conformation. Titration of the two-zinc insulin hexamer with anions high on the Hofmeister series such as SCN- causes marked changes in the NMR spectra which are interpreted as the result of major conformational changes to a new hexameric form of insulin having a twofold axis perpendicular to the threefold axis. Analysis of difference spectra indicates that this new hexamer (which should be capable of binding six zinc ions) binds 2 equiv of SCN- at two sites which are assumed to be identical and independent (K1 = 10(3), K2 = 2.5 X 10(2) M-1).     

Conformational studies of alanine oligopeptides by nuclear magnetic resonance.

We have studied the nmr spectra of the series of alanine oligopeptides containing a methoxyethoxyethoxyacetyl blocking group on the N-terminal residue and a morpholino blocking group on the C-terminal residue. Spectra were measured in chloroform–trifluoroacetic acid solvent systems. For oligomers with chain lengths of five or more, “double peaks” are observed for the α-CH protons. Addition of trifluoroacetic acid causes the peaks to coalesce. The amount of trifluoroacetic acid necessary for coalescence increases from the pentamer to the nonamer. These findings are general since alanine oligomers with different blocking groups exhibit similar “double peak” phenomena. We explain the “double peak” phenomenon in terms of specific folded forms of the oligopeptides which arise from intramolecular hydrogen bonding. Additional evidence for such hydrogen bonding is presented based upon infrared studies. Slight aggregation probably occurs for the pentamer and hexamer which may stabilize the folded forms.     

Conformational studies of N-Tyr-MIF-1 in aqueous solution by 1H nuclear magnetic resonance spectroscopy.

N-Tyr-MIF-1 (Tyr-Pro-Leu-Gly-NH2) is an endogenous brain peptide with multiple effects on animal behavior. However, there have been no studies on the conformation of this tetrapeptide. In this report, we studied the conformation of N-Tyr-MIF-1 in aqueous solution by conventional one-dimensional and two-dimensional (COSY and NOESY) 1H nuclear magnetic resonance spectroscopy at 300 MHz. A complete set of assignments for the resolved resonances and approximate assignments for the overlapping resonances were made. The results demonstrate that N-Tyr-MIF-1 is in slow exchange between two conformers, most likely determined by the cis and trans states of the proline residue. The minor conformation represents 30 +/- 3% of the population over the temperature range from 3 degrees to 73 degrees. In the major conformation, the tyrosine aromatic ring appears to be close enough to interact directly with the proline pyrrolidine ring, as indicated by a strong temperature dependence of the proline C beta H, C delta H and C delta H' chemical shifts. In contrast, this interaction of the tyrosine and proline rings is not present in the minor conformation.     

Conformational analysis of thyrotropin releasing factor by proton magnetic resonance spectroscopy

The proton magnetic resonance spectrum of thyrotropin releasing factor (TRF) in solution in deuterium oxide and deuterated dimethylsulfoxide (DMSO–d₆) has been analyzed. Two forms differing in cis–trans isomerism about the His-Pro peptide bond are observed. From the temperature dependence of chemical shift of the amide protons, it is concluded that TRF in DMSO–d₆ does not contain intramolecular hydrogen bonds. Measurement of NH? C_αH coupling constant provides an estimate of the histidine dihedral angle ?. Structural information about the histidine side-chain is deduced from C_αH? C_βH coupling constants and from the nonequivalence of the two prolyl δ-protons. In DMSO–d₆, there is evidence for a tautomeric equilibrium corresponding to an exchange of imidazole proton between the two nitrogen atoms N-δ and N-ε. In water, the N-εH tautomer is found to be the predominant tautomeric form of the imidazole ring. These results in combination with energy calculation, vibrational analysis, and carbon nmr studies allow the determination of the conformationof TRF.     

Nucleotide binding to tubulin-investigations by nuclear magnetic resonance spectroscopy

In an attempt to distinguish between the interaction of GTP and ATP with tubulin dimer, high-resolution ¹H- and ³¹P-NMR experiments have been carried out on the nucleotides in the presence of tubulin. The location of the ATP binding sites on the protein in relation to the GTP sites is still not clear. Using NMR spectroscopy, we have tried to address this question. Evidence for the existence of a site labelled as X-site and another site (labelled as L-site for both the nucleotides on tubulin has been obtained. It is suggested that this X-site is possibly the putative E-site. In order to gain further insight into the nature of these sites, the Mg(II at the N-site has been replaced by Mn(II and the paramagnetic effect of Mn(II on the linewidth of the proton resonances of tubulin-bound ATP and GTP has been studied. The results show that the L-site nucleotide is closer to the N-site metal ion compared to the X-site nucleotide. On the basis of these results, it is suggested that the L-site of ATP is distinct from the L-site of GTP while the X-site of both the nucleotides seems to be same. By using the paramagnetic effect of the metal ion, Mn(II), at the N-site on the relaxation rates of tubulin-bound ATP at L-site, distances of the protons of the base, sugar and phosphorous nuclei of the phosphorous moiety of ATP, from the N-site metal ion have been mapped. The base protons are 2 0.7–1 nm distant from the N-site metal ion, while the protons of the sugar are 2 0.8-1 nm from this metal ion site. On the other hand, the phosphorous nuclei of the phosphate groups are somewhat nearer (2 0.4–0.5 nm from the N-site metal ion.     

Conformational studies on the hypothalamic thyrotropin releasing factor and related compounds by 1-H nuclear magnetic resonance spectroscopy

Proton magnetic resonance studies at 220 MHz were carried out on the hypothalamic thyrotropin releasing factor (TRF) and a variety of synthetic analogs designed to yield specific information about side chain–side chain and side chain–backbone interactions. The results show that the very low field resonance position of one of the carboxamide protons observed for TRF dissolved in dimethylsulfoxide is neither caused by a seven-membered nor by a ten-membered hydrogen bonded ring, but rather is due to a short range interaction between the unprotonated histidyl side chain and the carboxamide residue. A systematic study of the preferred histidyl side chain conformation in various TRF analogs is in good agreement with this interpretation. It was demonstrated that this interaction is not strong enough to cause significant changes in the preferred back bone conformation of the hormone. The possibilities for typical dipole–dipole interaction are discussed. No such interaction has been detected in TRF dissolved in water. We conclude that the tertiary structure of TRF in polar solvents is determined primarily by the steric characteristics of the bulky side chains which maintain the molecule preferentially in an extended conformation.     

Elucidation of glycolipid structure by proton nuclear magnetic resonance spectroscopy

The primary structure of the oligosaccharide moiety of a glycosphingolipid can be elucidated by employing high-field proton nuclear magnetic resonance (NMR) spectroscopy. Information with respect to the composition and configuration of its sugar residues, and the sequence and linkage sites of the oligosaccharide chain can be obtained by employing a variety of one- and two-dimensional techniques. The latter include both scalar and dipolar correlated two-dimensional NMR spectroscopy. These techniques are also useful in establishing the solution conformation (secondary structure) of the oligosaccharide moiety. Examples in utilizing these techniques in elucidating the primary and secondary structures of glycolipids are presented.     

Conformational studies of the pentapeptides with weak adrenocorticotropin (ACTH) activities by means of nuclear magnetic resonance spectroscopy

The conformations of a pentapeptide L -His-L -Arg-L -Trp-Gly with weak adrenocorticotropin (ACTH) activity and its analogs, where each L -amino acid residue is substituted by D -residue, were investigated by means of proton and carbon-13 nmr spectroscopy on their DMSO-d₆ solutions. The spectra indicated the presence of slowly exchangeable conformation isomers for D -Phe and D -Arg analogs, due to steric hindrance around the arginine residue. The activation energy of the hindered rotation of the arginine side chain was estimated to be more than 19 ～ 20 kcal/mol. Spin-lattice relaxation times of carbon-13 nuclei also indicated slow segmental motion of the arginine side chain of the D analogs. An effect on proton chemical shifts by intermolecular electrostatic interaction between the arginine side chain and the C terminal carboxylic residue was observed. We did not observe, however, a direct correlation between pentapeptide activity and molecular conformation at this stage of the experiments.     

Biotransformations monitored in situ by proton nuclear magnetic resonance spectroscopy

One-dimensional Fourier-transform proton nuclear magnetic resonance (1H-NMR) spectroscopy can be used to study biotransformations in situ, in vivo and in aqua (1H2O). Although an insensitive method, it rapidly provides solution-structural information of mixtures of diverse compounds that are used and formed during enzymic reactions and culture fermentations; the samples do not require any physical or chemical processing for analysis. The absolute stereochemistry of some reactions can also be determined, and assessments of metabolic fluxes made. This technique, with appropriate modifications, is of obvious value for on-line assessments of industrial fermentation processes.     

Mechanisms of transmembrane cation transport studied by nuclear magnetic resonance spectroscopy

Several molecules like ionophores, vitamins, ion-binding cyclic peptides, acidic phospholipids, surfactants are known to expose the inner side of vesicles, to the externally added cations. Whereas ionophores and certain other systems bring about these changes by a selective transport (influx) of the cation by specialized mechanisms known as the carrier and channel mechanism, other systems cause lysis and vesicle fusion. These systems have been successfully studied using¹H,³¹ P and¹³C nuclear magnetic resonance spectroscopy after the demonstration, fifteen years ago, of the ability of paramagnetic lanthanide ions to distinguish the inside of the vesicle from the outside. The results of these ’nuclear magnetic resonance kinetics’ experiments are reviewed.     

Conformational characterization of synapse-associated protein 97 by nuclear magnetic resonance and small-angle X-ray scattering shows compact and elongated forms

Synapse-associated protein 97 (SAP97) is a membrane-associated guanylate kinase protein that interacts with other proteins such as ion channels, subunits of glutamate receptors, and other cytoskeletal proteins and molecular scaffolds. The molecular diversity of SAP97 results from alternative splicing at the N-terminus, and in the U1 and U5 regions. There are two main N-terminal isoforms: the β-isoform has an L27 domain, whereas in the α-isoform, this is replaced by a palmitoylation motif. We have used multiangle light scattering, nuclear magnetic resonance, and small-angle X-ray scattering studies to characterize the conformation of a truncated form of the β-isoform, hence mimicking the α-isoform. This paper provides a comprehensive view of the small-angle X-ray scattering data, and the resulting data show that the scattering data are consistent with the presence of an ensemble of forms in dynamic equilibrium, with two prominent populations of compact and extended forms, with R(g) values of 38 ± 7 ? (52%) and 70 ± 10 ? (37%), respectively. The data show that without the L27 domain, the conformation of SAP97 is biased toward the compact form. We propose a hypothesis in which the overall conformation of SAP97 is determined by the nature of the N-terminus, which may, in turn, influence the specific role of a particular splice variant.     

An introduction to biological nuclear magnetic resonance spectroscopy

Nuclear magnetic resonance (NMR) spectroscopy is one of the most powerful analytical techniques available to biology. This review is an introduction to the potential of this method and is aimed at readers who have little or no experience in acquiring or analyzing NMR spectra. We focus on spectroscopic applications of the magnetic resonance effect, rather than imaging ones, and explain how various aspects of the NMR phenomenon make it a versatile tool with which to address a number of biological problems. Using detailed examples, we discuss the use of ¹H NMR spectroscopy in mixture analysis and metabolomics, the use of ¹³C NMR spectroscopy in tracking isotopomers and determining the flux through metabolic pathways (‘fluxomics’) and the use of ³¹P NMR spectroscopy in monitoring ATP generation and intracellular pH homeotasis in vivo. Further examples demonstrate how NMR spectroscopy can be used to probe the physical environment of a cell by measuring diffusion and the tumbling rates of individual metabolites and how it can determine macromolecular structures by measuring the bonds and distances which separate individual atoms. We finish by outlining some of the key challenges which remain in NMR spectroscopy and we highlight how recent advances—such as increased magnet field strengths, cryogenic cooling, microprobes and hyperpolarisation—are opening new avenues for today's biological NMR spectroscopists.     

Biochemical characterization of cultivated Cordyceps bassiana mycelia and fruiting bodies by 1H nuclear magnetic resonance spectroscopy

In this study, nuclear magnetic resonance techniques coupled with multivariate data analysis were used for the metabolic profiling of mycelia and fruiting bodies of the entomopathogenic fungi, Cordyceps bassiana according to developmental stages. A direct extraction method using two deuterated solvents of D₂O and CDCl₃ was used to investigate the relative levels of identified metabolites in each extraction condition in the mycelium and fruiting body formation stages. There was a clear separation among mycelia and fruiting bodies with various developmental stages in partial least-squares discriminant analysis (PLS-DA) derived score plots. During the transition from mycelia to fruiting bodies, the major metabolic change observed was the conversion of glucose to mannitol, and beauvericin to phenylalanine and 1-hydroxyisovaleric acid. In the developmental stages of fruiting bodies studied, there was a clear separation between stage 3 and the other stages in PLS-DA derived score plots. Nineteen compounds including 13 amino acids, 2 nucleosides, 3 organic acids, and glucose showed the highest levels in stage 3 fruiting bodies. The flavonoid content in the fruiting bodies showed similar levels during stages 1, 2, and 3, whereas the level at stage 4 was significantly decreased compared to the other stages. Results suggest that the fruiting body of C. bassiana is richer in natural resources at stage 3 compared to the other fruiting body stages due to its high abundance of compounds including total flavonoids. The metabolome information acquired in this study can be useful criteria for the quality control of commercial use of C. bassiana.