Pyranose Ring Puckering Thermodynamics for Glycan Monosaccharides Associated with Vertebrate Proteins

The conformational properties of carbohydrates can contribute to protein structure directly through covalent conjugation in the cases of glycoproteins and proteoglycans and indirectly in the case of transmembrane proteins embedded in glycolipid-containing bilayers. However, there continue to be sign...

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Bibliographic Details
Published in:International journal of molecular sciences 2021-12, Vol.23 (1), p.473
Main Authors: Guvench, Olgun, Martin, Devon, Greene, Megan
Format: Article
Language:English
Subjects:
Adaptive systems
Animals
Bias
Biology
Biomolecules
Carbohydrate Conformation
Carbohydrates
Conjugation
Crystallography
Flexibility
galactose
GalNAc
GlcNAc
glucose
Glycan
Glycolipids
Glycoproteins
Lipids
mannose
Membrane proteins
Molecular dynamics
Monosaccharides
Monosaccharides - chemistry
Parameterization
Polysaccharides - chemistry
Protein structure
Proteins
Proteoglycans
Simulation
Solvents
Thermodynamics
Vertebrates
xylose
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Summary:The conformational properties of carbohydrates can contribute to protein structure directly through covalent conjugation in the cases of glycoproteins and proteoglycans and indirectly in the case of transmembrane proteins embedded in glycolipid-containing bilayers. However, there continue to be significant challenges associated with experimental structural biology of such carbohydrate-containing systems. All-atom explicit-solvent molecular dynamics simulations provide a direct atomic resolution view of biomolecular dynamics and thermodynamics, but the accuracy of the results depends on the quality of the force field parametrization used in the simulations. A key determinant of the conformational properties of carbohydrates is ring puckering. Here, we applied extended system adaptive biasing force (eABF) all-atom explicit-solvent molecular dynamics simulations to characterize the ring puckering thermodynamics of the ten common pyranose monosaccharides found in vertebrate biology (as represented by the CHARMM carbohydrate force field). The results, along with those for idose, demonstrate that the CHARMM force field reliably models ring puckering across this diverse set of molecules, including accurately capturing the subtle balance between C and C chair conformations in the cases of iduronate and of idose. This suggests the broad applicability of the force field for accurate modeling of carbohydrate-containing vertebrate biomolecules such as glycoproteins, proteoglycans, and glycolipids.
ISSN:1422-0067
1661-6596
1422-0067
DOI:10.3390/ijms23010473