Exploration of Conformational Spaces of High‐Mannose‐Type Oligosaccharides by an NMR‐Validated Simulation

Yamaguchi, Takumi; Sakae, Yoshitake; Zhang, Ying; Yamamoto, Sayoko; Okamoto, Yuko; Kato, Koichi

doi:10.1002/anie.201406145

Cited by 65 publications

(41 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This demonstrates that paramagnetism-assisted NMR could be applicable to the determination of the 3D conformations of oligosaccharides in solution, if the molecule could be sufficiently rigid. Furthermore, the introduction of lanthanide tags causes distinct PCSs even for identical non-reducing terminal groups in multiantenary oligosaccharides, resolving their severely overlapping peaks and facilitating spectral analysis [60,61].…”

Section: Conformational Analyses Of Sugar Chains Based On Paramagnetimentioning

confidence: 99%

“…PCS-based conformational analysis has also been applied to complex-type and high-mannose-type oligosaccharides [60,61]. A triantennary oligosaccharide containing nine mannose residues, M9, as well as its derivative M8B was overexpressed in genetically engineered yeast cells as fully 13 C-labeled forms [62,63] and attached to an EDTA-based lanthanide-chelating tag (Fig.…”

Section: Exploration Of the Conformational Dynamics Of Oligosaccharidesmentioning

confidence: 99%

See 1 more Smart Citation

Paramagnetic NMR probes for characterization of the dynamic conformations and interactions of oligosaccharides

Kato

Yamaguchi

2015

Glycoconj J

Self Cite

View full text Add to dashboard Cite

Paramagnetism-assisted nuclear magnetic resonance (NMR) techniques have recently been applied to a wide variety of biomolecular systems, using sophisticated immobilization methods to attach paramagnetic probes, such as spin labels and lanthanide-chelating groups, at specific sites of the target biomolecules. This is also true in the field of carbohydrate NMR spectroscopy. NMR analysis of oligosaccharides is often precluded by peak overlap resulting from the lack of variability of local chemical structures, by the insufficiency of conformational restraints from nuclear Overhauser effect (NOE) data due to low proton density, and moreover, by the inherently flexible nature of carbohydrate chains. Paramagnetic probes attached to the reducing ends of oligosaccharides cause paramagnetic relaxation enhancements (PREs) and/or pseudocontact shifts (PCSs) resolve the peak overlap problem. These spectral perturbations can be sources of long-range atomic distance information, which complements the local conformational information derived from J couplings and NOEs. Furthermore, paramagnetic NMR approaches, in conjunction with computational methods, have opened up possibilities for the description of dynamic conformational ensembles of oligosaccharides in solution. Several applications of paramagnetic NMR techniques are presented to demonstrate their utility for characterizing the conformational dynamics of oligosaccharides and for probing the carbohydrate-recognition modes of proteins. These techniques can be applied to the characterization of transient, non-stoichiometric interactions and will contribute to the visualization of dynamic biomolecular processes involving sugar chains.

show abstract

Section: Conformational Analyses Of Sugar Chains Based On Paramagnetimentioning

confidence: 99%

Section: Exploration Of the Conformational Dynamics Of Oligosaccharidesmentioning

confidence: 99%

Paramagnetic NMR probes for characterization of the dynamic conformations and interactions of oligosaccharides

Kato

Yamaguchi

2015

Glycoconj J

Self Cite

View full text Add to dashboard Cite

show abstract

“…[6] This methodology has first been applied to the study of small oligosaccharides (di-, tri-, and tetrasaccharides), [7][8][9][10][11] then to N-glycans.T he conformational properties of complex-type bi-antennary and high-mannosetype N-glycans were elucidated and could be resolved in each case down to the level of individual branches. [4,5] Proceeding from this experimental basis,weherein extend this concept to the level of high-degree branching,and show that it is possible to experimentally characterize the conformational behavior and recognition properties of ag alactosylated complex-type tetra-antennary N-glycan, which is not possible by standard NMR methods owing to chemical shift degeneracyo ft he glycan. We have then tested the hypothesis of branch selectivity for two N-acetyllactosamine-binding lectins, Datura stramonium seed lectin (DSL) and Ricinus Communis agglutinin (RCA1 20).…”

mentioning

confidence: 94%

“…[4,5] Proceeding from this experimental basis,weherein extend this concept to the level of high-degree branching,and show that it is possible to experimentally characterize the conformational behavior and recognition properties of ag alactosylated complex-type…”

mentioning

confidence: 95%

“…As ap romising approach, carbohydrates conjugated to lanthanide-binding tags have shown high potential toward this aim. [4,5] In its vicinity,acomplexed paramagnetic ion induces significant chemical shift changes of the NMR signals of the glycan as ar esult of dipolar interactions involving the unpaired electron of the metal. These pseudocontact shifts (PCS) depend on the distance between each proton and the metal (proportional to 1/r 3 ).…”

mentioning

confidence: 99%

See 1 more Smart Citation

Breaking the Limits in Analyzing Carbohydrate Recognition by NMR Spectroscopy: Resolving Branch‐Selective Interaction of a Tetra‐Antennary N‐Glycan with Lectins

et al. 2017

View full text Add to dashboard Cite

The biological recognition of complex-type Nglycans is part of many key physiological and pathological events.Despite their importance,the structural characterization of these events remains unsolved. The inherent flexibility of Nglycans hampers crystallization and the chemical equivalence of individual branches precludes their NMR characterization. By using achemoenzymatically synthesized tetra-antennary Nglycan conjugated to al anthanide binding tag,t he NMR signals under paramagnetic conditions discriminated all four N-acetyl lactosamine antennae with unprecedented resolution. The NMR data revealed the conformation of the N-glycan and permitted for the first time the direct identification of individual branches involved in the recognition by two N-acetyllactosamine-binding lectins,D atura stramonium seed lectin (DSL) and Ricinus Communis agglutinin (RCA120).N-glycans are ubiquitous in nature and functionalize glycoproteins.[1] Protein glycosylation is required for proper biological and biophysical function and often, alterations in glycosylation are related to diseases. [2] Complex glycosylation patterns containing multi-antennary N-glycans are typically found in mature glycoproteins. However,t he structural characterization of these glycans is rather challenging.U sually,N MR spectroscopy and X-ray diffraction techniques fail to provide specific answers on the structure and molecular recognition features owing to the intrinsic attributes of the glycan. Thep roperties of the glycosidic bond and especially the presence of 1-6 linkages endow al arge flexibility to the molecule.T his feature precludes crystallization or hampers the detection of enough electron density for most of the glycan part in the X-ray analysis of glycoproteins.Moreover,the standard use of the corresponding fitting programs to deduce three-dimensional structures frequently give rise to incorrect structures of the glycans.[3] Thus,a ny advance in this area is of high value. As ap romising approach, carbohydrates conjugated to lanthanide-binding tags have shown high potential toward this aim. [4,5] In its vicinity,acomplexed paramagnetic ion induces significant chemical shift changes of the NMR signals of the glycan as ar esult of dipolar interactions involving the unpaired electron of the metal. These pseudocontact shifts (PCS) depend on the distance between each proton and the metal (proportional to 1/r 3 ).[6] This methodology has first been applied to the study of small oligosaccharides (di-, tri-, and tetrasaccharides), [7][8][9][10][11] then to N-glycans.T he conformational properties of complex-type bi-antennary and high-mannosetype N-glycans were elucidated and could be resolved in each case down to the level of individual branches. [4,5] Proceeding from this experimental basis,weherein extend this concept to the level of high-degree branching,and show that it is possible to experimentally characterize the conformational behavior and recognition properties of ag alactosylated complex-type

show abstract

Breaking the Limits in Analyzing Carbohydrate Recognition by NMR Spectroscopy: Resolving Branch‐Selective Interaction of a Tetra‐Antennary N‐Glycan with Lectins

et al. 2017

View full text Add to dashboard Cite

The biological recognition of complex‐type N‐glycans is part of many key physiological and pathological events. Despite their importance, the structural characterization of these events remains unsolved. The inherent flexibility of N‐glycans hampers crystallization and the chemical equivalence of individual branches precludes their NMR characterization. By using a chemoenzymatically synthesized tetra‐antennary N‐glycan conjugated to a lanthanide binding tag, the NMR signals under paramagnetic conditions discriminated all four N‐acetyl lactosamine antennae with unprecedented resolution. The NMR data revealed the conformation of the N‐glycan and permitted for the first time the direct identification of individual branches involved in the recognition by two N‐acetyllactosamine‐binding lectins, Datura stramonium seed lectin (DSL) and Ricinus Communis agglutinin (RCA120).

show abstract

Exploration of Conformational Spaces of High‐Mannose‐Type Oligosaccharides by an NMR‐Validated Simulation

Cited by 65 publications

References 39 publications

Paramagnetic NMR probes for characterization of the dynamic conformations and interactions of oligosaccharides

Paramagnetic NMR probes for characterization of the dynamic conformations and interactions of oligosaccharides

Breaking the Limits in Analyzing Carbohydrate Recognition by NMR Spectroscopy: Resolving Branch‐Selective Interaction of a Tetra‐Antennary N‐Glycan with Lectins

Breaking the Limits in Analyzing Carbohydrate Recognition by NMR Spectroscopy: Resolving Branch‐Selective Interaction of a Tetra‐Antennary N‐Glycan with Lectins

Contact Info

Product

Resources

About