Combining pure shift and J-edited spectroscopies: A strategy for extracting chemical shifts and scalar couplings from highly crowded proton spectra of oligomeric saccharides.

We report the application of pure shift and J-edited nuclear magnetic resonance spectroscopies to the structural analysis of a protected maltotrioside synthetic intermediate whose crowded 1 H spectrum displays highly crowded regions. The analytical strategy is based on the implementation of J-edited and TOCSY experiments whose resolution is optimized by the use of broadband homonuclear decoupling and selective refocusing techniques, to assign and measure chemical shifts and homonuclear scalar couplings with high accuracy. The resulting data show a high level of complementarity, providing a detailed insight into each subunit of this oligomeric saccharide, even for proton sites whose nuclear magnetic resonance signals strongly overlap. This approach allowed for fully assigning proton chemical shifts and extracting 80% of the 3 JHH couplings that are in excellent agreement with those expected for D-gluco-pyranosyl units in 4 C1 conformations.

Magnetic field dependence of spatial frequency encoding NMR as probed on an oligosaccharide.

The magnetic field dependence of spatial frequency encoding NMR techniques is addressed through a detailed analysis of (1)H NMR spectra acquired under spatial frequency encoding on an oligomeric saccharide sample. In particular, the influence of the strength of the static magnetic field on spectral and spatial resolutions that are key features of this method is investigated. For this purpose, we report the acquisition of correlation experiments implementing broadband homodecoupling or J-edited spin evolutions, and we discuss the resolution enhancements that are provided by these techniques at two different magnetic fields. We show that performing these experiments at higher field improves the performance of high resolution NMR techniques based on a spatial frequency encoding. The significant resolution enhancements observed on the correlation spectra acquired at very high field make them valuable analytical tools that are suitable for the assignment of (1)H chemical shifts and scalar couplings in molecules with highly crowded spectrum such as carbohydrates.

Desorption electrospray ionization mass spectrometry of glycosaminoglycans and their protein noncovalent complex.

Glycosaminoglycans heparin and heparan sulfate are biologically active polysulfated carbohydrates that are among the most challenging biopolymers with regards to their structural analysis and functional assessment. Fragmentation of oligosaccharides and sulfate loss are important hindrance to their analysis by mass spectrometry (MS), requiring thus soft ionization methods. The recently introduced soft ionization method desorption electrospray ionization (DESI) has been applied here to heparin and heparan sulfate oligosaccharides, showing that DESI-MS is well suited for the detection of such fragile biomolecules in their intact form. Characterization of complicated oligosaccharides such as synthetic heparin octadecasulfated dodecasaccharide was successfully achieved. The use of water for a spray solvent instead of denaturing organic solvents allowed the first DESI-MS detection of noncovalent biomolecular complexes between heparin oligosaccharides and the chemokine Stromal Cell-derived Factor-1. The hyphenation of the DESI ion source with the high-resolution LTQ-Orbitrap MS analyzer led to high accuracy of mass measurement and enabled unambiguous determination of the protein-bound sulfated oligosaccharide.

Chemical fatty acylation confers hemolytic and toxic activities to adenylate cyclase protoxin of Bordetella pertussis.

Adenylate cyclase toxin (ACT), a virulence factor of Bordetella pertussis, acquires hemolytic and toxic activities after post-translational modification of the cyaA gene product, CyaA. The exact nature of this modification is unknown, but homology to the related repeat toxin alpha-hemolysin of Escherichia coli suggests that fatty acylation of a lysine residue may be involved. In the present study, we used an in vitro chemical approach to acylate unmodified, inactive adenylate cyclase protoxin by using a new water-soluble compound, acylpyrophosphate. We show that undirected transfer of lauric, myristic, or palmitic acid chains to the CyaA protoxin is able to confer both hemolytic and toxic activities to ACT. The chemically modified protoxin shows a specific requirement for Ca2+ ions for toxic activity, as does the wild type toxin. However, the toxic and hemolytic activities of chemically modified ACT are low in comparison to ACT modified in vivo, suggesting that in vitro fatty acylation of the protoxin involves random modification of nucleophilic residues present in the toxin in contrast to the in vivo modification of specific sites.