Characterization of human liver 3-O-beta-D-glucopyranuronosyl-cholesterol by mass spectrometry and nuclear magnetic resonance spectroscopy

We have isolated an unusual acidic glycolipid which was detected in the lower phase of the Folch partition of the total lipid extract of human liver during a routine isolation of glycosphingolipids. With the solvent systems commonly used for thin-layer chromatography of glycosphingolipids, this glycolipid has a mobility similar to GbOse3Cer, one of the major glycosphingolipids in human liver. Free cholesterol was released from this glycolipid upon treatment with beta-glucuronidase. The electron impact mass spectrum of the permethylated derivative of this glycolipid showed an intense peak at m/e 369 which is consistent with the cholesterol part of the molecule. It also showed m/e 233 and 201 which are derived from the permethylated glucopyranuronosyl residue. The final proof of the structure was accomplished by high resolution NMR spectroscopy which revealed the presence of beta-linked glucopyranuronosyl residue and cholesterol. Thus, the structure of this acidic glycolipid was conclusively established to be 3-O-beta-D-glucopyranuronosyl-cholesterol.     

3-Hydroxy-3-methylglutaryl-CoA lyase deficiency studied using 2-dimensional proton nuclear magnetic resonance spectroscopy

1H-NMR spectroscopy has been applied to identify components in the urine of subjects with a deficiency of the enzyme 3-hydroxy-3-methylglutaryl-CoA lyase. One-dimensional spectra of samples from a pair of non-identical twins with this disorder were very similar and are probably diagnostic. The most intense signals were from singlets. Complete assignment of these major components was made possible by the use of 2-dimensional chemical shift correlated spectroscopy since several long-range couplings were detected. 2-dimensional spectroscopic techniques may therefore be of value in the identification of singlets in multicomponent systems.     

Discrimination of steatosis and NASH in mice using nuclear magnetic resonance spectroscopy

Nonalcoholic fatty liver disease (NAFLD) is a common cause of hepatic dysfunction. The disease spectrum ranges from hepatic steatosis to nonalcoholic steatohepatitis (NASH). The aim of this study was to identify metabolic differences in murine models of simple hepatic steatosis and NASH for the distinction of these NAFLD stages. For 12 weeks, male BALB/c mice were fed either a control or two different high-fat diets leading to hepatic steatosis and NASH, respectively. Metabolic differences were determined by independent component analysis (ICA) of nuclear magnetic resonance (NMR) spectra of lipophilic and hydrophilic liver extracts, and urine specimens. The results from ICA clearly discriminated the three investigated groups. Discriminatory biomarkers in the lipophilic liver extracts were free cholesterol, cholesterol ester and lipid methylene. Discrimination of the hydrophilic liver extracts was mainly mediated by betaine, glucose, and lactate, whereas in urine taurine, trimethylamine-N-oxide, and trimethylamine were the most discriminatory biomarkers. In conclusion, NMR metabolite fingerprinting of spot urine specimens may allow the noninvasive distinction of steatosis and NASH.     

Spatial structure determination of antiarrhythmic peptide using nuclear magnetic resonance spectroscopy

The peptide AAP10 was synthesized according to the Merrifield technique following the Fmoc-strategy and its spatial structure in aqueous solution studied with NMR principles. It is known from previous studies that the peptide has antiarrhythmic activity and inhibits cardiac ischemia induced alterations of the activation pattern, decreases the activation–recovery interval (ARI) dispersion and improves cellular coupling via enhancement of gap junction conductance (2, 2, 3, 4). The peptide was synthesized as a peptide amide. Two different semi cyclic conformations were characterized.     

Chemical proteomics from a nuclear magnetic resonance spectroscopy perspective

Proteomics is the study of the protein complement of a genome and employs a number of newly emerging tools. One such tool is chemical proteomics, which is a branch of proteomics devoted to the exploration of protein function using both in vitro and in vivo chemical probes. Chemical proteomics aims to define protein function and mechanism at the level of directly observed protein-ligand interactions, whereas chemical genomics aims to define the biological role of a protein using chemical knockouts and observing phenotypic changes. Chemical proteomics is therefore traditional mechanistic biochemistry performed in a systems-based manner, using either activity- or affinity-based probes that target proteins related by chemical reactivities or by binding site shape/properties, respectively. Systems are groups of proteins related by metabolic pathway, regulatory pathway or binding to the same ligand. Studies can be based on two main types of proteome samples: pooled proteins (1 mixture of N proteins) or isolated proteins in a given system and studied in parallel (N single protein samples). Although the field of chemical proteomics originated with the use of covalent labeling strategies such as isotope-coded affinity tagging, it is expanding to include chemical probes that bind proteins noncovalently, and to include more methods for observing protein-ligand interactions. This review presents an emerging role for nuclear magnetic resonance spectroscopy in chemical proteomics, both in vitro and in vivo. Applications include: functional proteomics using cofactor fingerprinting to assign proteins to gene families; gene family-based structural characterizations of protein-ligand complexes; gene family-focused design of drug leads; and chemical proteomic probes using nuclear magnetic resonance SOLVE and studies of protein-ligand interactions in vivo.     

Chemical proteomics from a nuclear magnetic resonance spectroscopy perspective

Proteomics is the study of the protein complement of a genome and employs a number of newly emerging tools. One such tool is chemical proteomics, which is a branch of proteomics devoted to the exploration of protein function using both in vitro and in vivo chemical probes. Chemical proteomics aims to define protein function and mechanism at the level of directly observed protein–ligand interactions, whereas chemical genomics aims to define the biological role of a protein using chemical knockouts and observing phenotypic changes. Chemical proteomics is therefore traditional mechanistic biochemistry performed in a systems-based manner, using either activity- or affinity-based probes that target proteins related by chemical reactivities or by binding site shape/properties, respectively. Systems are groups of proteins related by metabolic pathway, regulatory pathway or binding to the same ligand. Studies can be based on two main types of proteome samples: pooled proteins (1 mixture of N proteins) or isolated proteins in a given system and studied in parallel (N single protein samples). Although the field of chemical proteomics originated with the use of covalent labeling strategies such as isotope-coded affinity tagging, it is expanding to include chemical probes that bind proteins noncovalently, and to include more methods for observing protein–ligand interactions. This review presents an emerging role for nuclear magnetic resonance spectroscopy in chemical proteomics, both in vitro and in vivo. Applications include: functional proteomics using cofactor fingerprinting to assign proteins to gene families; gene family-based structural characterizations of protein–ligand complexes; gene family-focused design of drug leads; and chemical proteomic probes using nuclear magnetic resonance SOLVE and studies of protein–ligand interactions in vivo.     

Characterization of anti-Z-DNA antibody binding sites on Z-DNA by nuclear magnetic resonance spectroscopy

Two monoclonal anti-Z-DNA antibodies, Z22 and Z44, were shown to bind to the oligonucleotides, d(CG)2 and d(CG)3, and to interact with different parts of the helix. 1H nuclear magnetic resonance spectroscopy showed that Fab fragments stabilize an ordered structure in the tetranucleotide d(CG)2. Nuclear Overhauser effects measured in the presence of Z22 Fab indicate a syn conformation of guanine residues of d(CG)2. Intermolecular transfer of saturation between the Fabs and bound d(CG)3 was detected by a saturation of the protein spectrum and observation of changes in the DNA spectrum. Antibodies with deuterated aromatic amino acids were prepared to eliminate the protein aromatic resonances and thereby allow a more detailed analysis of the transfer to the DNA base protons. The greatest transfer with Z44 was to the dC-5 protons although all of the base protons interact with this antibody. Little, if any, transfer to the DNA base protons was observed with Z22. These results are consistent with a Z44 binding site on the convex surface of the Z-helix (analogous to the major groove of B-DNA) and a Z22 binding site on the sugar-phosphate backbone.     

Characterization of a novel interaction between ELMO1 and ERM proteins

ERMs are closely related proteins involved in cell migration, cell adhesion, maintenance of cell shape, and formation of microvilli through their ability to cross-link the plasma membrane with the actin cytoskeleton. ELMO proteins are also known to regulate actin cytoskeleton reorganization through activation of the small GTPbinding protein Rac via the ELMO-Dock180 complex. Here we showed that ERM proteins associate directly with ELMO1 as purified recombinant proteins in vitro and at endogenous levels in intact cells. We mapped ERM binding on ELMO1 to the N-terminal 280 amino acids, which overlaps with the region required for binding to the GTPase RhoG, but is distinct from the C-terminal Dock180 binding region. Consistent with this, ELMO1 could simultaneously bind both radixin and Dock180, although radixin did not alter Rac activation via the Dock180-ELMO complex. Most interestingly, radixin binding did not affect ELMO binding to active RhoG and a trimeric complex of active RhoG-ELMO-radixin could be detected. Moreover, the three proteins colocalized at the plasma membrane. Finally, in contrast to most other ERM-binding proteins, ELMO1 binding occurred independently of the state of radixin C-terminal phosphorylation, suggesting an ELMO1 interaction with both the active and inactive forms of ERM proteins and implying a possible role of ELMO in localizing or retaining ERM proteins in certain cellular sites. Together these data suggest that ELMO1-mediated cytoskeletal changes may be coordinated with ERM protein crosslinking activity during dynamic cellular functions.     

Structural and conformational analysis of sialyloligosaccharides using carbon-13 nuclear magnetic resonance spectroscopy

The analysis of the carbon-13 chemical shift data of NeuAc alpha (2----3)Gal beta (1----4)Glc and NeuAc alpha (2----3)Gla beta-(1----4)GlcNAc and their respective NeuAc alpha (2----6) isomers established distinct and different conformations of the sialic acid residue, depending on the type of anomeric linkage [alpha-(2----3) vs. alpha (2----6)]. Interactions between the NeuAc residue and the Glc or GlcNAc residue are particularly strong in the case of the alpha (2----6) isomers. Similar effects are observed for the larger oligosaccharides [II3(NeuAc)2Lac and IV6NeuAcLcOse4] and even in intact glycoproteins and polysaccharides. It is proposed that the NeuAc alpha (2----3) isomers assume an extended conformation with the sialic residue at the end (terminal) of the oligosaccharide chain or branch. The NeuAc alpha (2----6) isomers are assumed to be folded back toward the inner core sugar residues.     

Structure determination of biological macromolecules in solution using nuclear magnetic resonance spectroscopy

A detailed understanding of the function of a biological macromolecule requires knowledge of its three-dimensional structure. Most atomic-resolution structures of biological macromolecules have been solved either by X-ray diffraction in single crystals or by nuclear magnetic resonance (NMR) in solution. This review surveys the method of NMR structure determination. First, a brief introduction to NMR and its basic concepts is presented. The main part of the article deals with the individual steps necessary for an NMR structure determination. At the end, the discussion turns to considerations on the influence of the molecular size of the macromolecules on the structure determination by NMR. New techniques are discussed that greatly enhance the possibilities of applying NMR to large molecular systems.     

Differentiation between hemosiderin- and ferritin-bound brain iron using nuclear magnetic resonance and magnetic resonance imaging.

MRI is an optimal clinical (research) tool to provide information on brain morphology and pathology and to detect metal ions that possess intrinsic magnetic properties. Non-heme iron is abundantly present in the brain in three different forms: "low molecular weight" complexes, iron bound to "medium molecular weight complexes" metalloproteins such as transferrin, and "high molecular weight" complexes as ferritin and hemosiderin. The total amount and form of iron may differ in health and disease, and MRI can possibly quantify and monitor such changes. Ferritin-bound iron is the main storage form of iron and is present predominantly in the extrapyramidal nuclei where its amounts normally increase as a function of age. Ferritin is water soluble and shortens both, T1 and T2 relaxation, with as result a signal change on the MR images. Hemosiderin, a degradation product of ferritin, is water-insoluble with a stronger T2 shortening effect than ferritin. The larger cluster size of hemosiderin and its water-insolubility also explain a lack of significant T1-shortening effect on T1-weighted images. Using both in vitro specimens and intact brain tissue in vivo we demonstrate here that MRI may be able to distinguish between ferritin- and hemosiderin-bound iron.     

Characterization of trotter horses urine metabolome by means of proton nuclear magnetic resonance spectroscopy

Background

Metabolomics has been recognized as a powerful approach for disease screening. In order to highlight potential health issues in subjects, a key factor is the possibility to compare quantitatively the metabolome of their biofluids with reference values from healthy individuals. Such efforts towards the systematic characterization of the metabolome of biofluids in perfect health conditions, far from concluded for humans, have barely begun on horses.

Objectives

The present work attempts, for the first time, to give reference quantitative values for the molecules mostly represented in the urine metabolome of horses at rest and under light training, as observable by ¹H-NMR.

Methods

The metabolome of ten trotter horses, four male and six female, ranging from 3 to 8 years of age, has been observed by ¹H-NMR spectroscopy before and after three training sessions.

Results

We could characterize and quantify 54 molecules in trotter horse urine, originated from diet, protein digestion, energy generation or gut-microbial co-metabolism.

Conclusion

We were able to describe how gender, age and exercise affected their concentration, by means of a two steps protocol based on univariate and robust principal component analysis.

     

Study of specific interaction between nucleotides and dye support by nuclear magnetic resonance

The binding between four matrices (beaded cellulose, cellulose acetate, cellulose triacetate and Sepharose CL-6B) and beaded cellulose derivatized with a thiacarbocyanine dye with 5'-mononucleotides is investigated by Saturation Transfer Difference Nuclear Magnetic Resonance (STD-NMR) technique. This procedure intends to identify unspecific interactions between 5'-mononucleotides and matrices commonly used in affinity chromatography systems and also clarify the contribution of a thiacarbocyanine dye immobilized onto cellulose beads in a biorecognition process. The differences between non-derivatized and derivatized beaded cellulose evidence the contribution of thiacarbocyanine dye in the observed interaction. STD-NMR experiments show that Sepharose CL- 6B interact less with the 5'-mononucleotides comparatively with beaded cellulose. Indeed, beaded cellulose shows nonspecific interactions with almost all 5'-mononucleotides that compromises the specificity of the interaction between the thiacarbocyanine dye immobilized with the 5'-mononucleotides. The cellulose matrices where the hydroxyl groups are replaced by acetate and triacetate groups do not exhibit binding response to the 5'- mononucleotides, whereas the thiacarbocyanine dye contribution is evidenced by the reinforcement of the interactions with the sugar moiety of 5'-GMP and 5'-UMP and with base of 5'-AMP, 5'-CMP and 5'-TMP. This screening of the nucleotide atoms involved in the binding to the supports can be very useful in chromatography evaluations in which dye-affinity chromatography supports may be used, such as purification of nucleic acids.     

Surface plasmon resonance and nuclear magnetic resonance studies of ABAD-Abeta interaction

Abeta binding alcohol dehydrogenase (ABAD) is an NAD-dependent mitochondrial dehydrogenase. The binding between ABAD and Abeta is likely a direct link between Abeta and mitochondrial toxicity in Alzheimer's disease. In this study, surface plasmon resonance (SPR) was employed to determine the temperature dependence of the affinity of the ABAD-Abeta interaction. A van't Hoff analysis revealed that the ABAD-Abeta association is driven by a favorable entropic change (DeltaS = 300 +/- 30 J mol-1 K-1) which overcomes an unfavorable enthalpy change (DeltaH = 49 +/- 7 kJ/mol). Therefore, hydrophobic interactions and changes in protein dynamics are the dominant driving forces of the ABAD-Abeta interaction. This is the first dissection of the entropic and enthalpic contribution to the energetics of a protein-protein interaction involving Abeta. SPR confirmed the conformational changes in the ABAD-Abeta complex after Abeta binding, consistent with differences seen in the crystal structures of free ABAD and the ABAD-Abeta complex. Saturation transfer difference (STD) NMR experiments directly and unambiguously demonstrated the inhibitory effect of Abeta on the ABAD-NAD interaction. Conversely, NAD inhibits the Abeta-ABAD interaction. Binding of Abeta and binding of NAD to ABAD are likely mutually exclusive. Thus, Abeta binding induces conformational and subsequently functional changes in ABAD, which may have a role in the mechanism of Abeta toxicity in Alzheimer's disease.     

Rapid identification of Candida species by using nuclear magnetic resonance spectroscopy and a statistical classification strategy

Nuclear magnetic resonance (NMR) spectra were acquired from suspensions of clinically important yeast species of the genus Candida to characterize the relationship between metabolite profiles and species identification. Major metabolites were identified by using two-dimensional correlation NMR spectroscopy. One-dimensional proton NMR spectra were analyzed by using a staged statistical classification strategy. Analysis of NMR spectra from 442 isolates of Candida albicans, C. glabrata, C. krusei, C. parapsilosis, and C. tropicalis resulted in rapid, accurate identification when compared with conventional and DNA-based identification. Spectral regions used for the classification of the five yeast species revealed species-specific differences in relative amounts of lipids, trehalose, polyols, and other metabolites. Isolates of C. parapsilosis and C. glabrata with unusual PCR fingerprinting patterns also generated atypical NMR spectra, suggesting the possibility of intraspecies discontinuity. We conclude that NMR spectroscopy combined with a statistical classification strategy is a rapid, nondestructive, and potentially valuable method for identification and chemotaxonomic characterization that may be broadly applicable to fungi and other microorganisms.     

Determination of the three-dimensional solution structure of barnase using nuclear magnetic resonance spectroscopy

The solution conformation of the ribonuclease barnase has been determined by using 1H nuclear magnetic resonance (NMR) spectroscopy. The 20 structures were calculated by using 853 interproton distance restraints obtained from analyses of two-dimensional nuclear Overhauser spectra, 72 phi and 53 chi 1 torsion angle restraints, and 17 hydrogen-bond distance restraints. The calculated structures contain two alpha-helices (residues 6-18 and 26-34) and a five-stranded antiparallel beta-sheet (residues 50-55, 70-75, 85-91, 94-101, and 105-108). The core of the protein is formed by the packing of one of the alpha-helices (residues 6-18) onto the beta-sheet. The average RMS deviation between the calculated structures and the mean structure is 1.11 A for the backbone atoms and 1.75 A for all atoms. The protein is least well-defined in the N-terminal region and in three large loops. When these regions are excluded, the average RMS deviation between the calculated structures and the mean structure for residues 5-34, 50-56, 71-76, 85-109 is 0.62 A for the backbone atoms and 1.0 A for all atoms. The NMR-derived structure has been compared with the crystal structure of barnase [Mauguen et al. (1982) Nature (London) 297, 162-164].     

Conformation of 1- and 3-deazaadenosines in solution as studied by 1H nuclear magnetic resonance spectroscopy.

¹H nuclear magnetic resonance spectra of 1 - (II) and 3-deazaadenosines (III) together with adenosine (I) in dimethylsulfoxide have been examined. Features of coupling constants indicate that the furanose rings of I, II, and III have similar conformational preferences and that conformations about the 4′-C–5′-C bond are preferentially $\text{gauche-gauche}$. Nuclear Overhauser effect and spin-lattice relaxation-time measurements demonstrate that II predominantly adopts the $\text{syn}$-conformation similar to that of I, whereas that of III has a greater $\text{anti}$ (freely rotating) component. The results suggest that the $\text{syn}$-conformation in II as well as I is stabilized presumably through a hydrogen bond between the 3-N and 5′-hydroxyl group.