A combined nuclear magnetic resonance and molecular dynamics study of the two structural motifs for mixed-linkage ß-glucans: methyl ß-cellobioside and methyl ß-laminarabioside

Niels Johan Christensen; Peter Ibsen Hansen; Flemming Hofmann Larsen; Tore Folkerman; Mohammed Saddik Motawie; Søren Balling Engelsen

doi:10.1016/j.carres.2009.12.009

A combined nuclear magnetic resonance and molecular dynamics study of the two structural motifs for mixed-linkage ß-glucans: methyl ß-cellobioside and methyl ß-laminarabioside

Niels Johan Christensen, Peter Ibsen Hansen, Flemming Hofmann Larsen, Tore Folkerman, Mohammed Saddik Motawie, Søren Balling Engelsen

22 Citations (Scopus)

Abstract

The conformational and hydration properties of the two disaccharides methyl β-cellobioside and methyl β-laminarabioside were investigated by NMR spectroscopy and explicit solvation molecular dynamics simulations using the carbohydrate solution force field (CSFF). Adiabatic maps produced with this force field displayed 4 minima A: (Φ = 300°, Ψ = 280°), B: (Φ = 280°, Ψ = 210°), C: (Φ = 260°, Ψ = 60°), and D: (Φ = 60°, Ψ = 260°) for methyl β-cellobioside and 3 minima A: (Φ = 290°, Ψ = 130°), B: (Φ = 270°, Ψ = 290°), and C: (Φ = 60°, Ψ = 120°) for methyl β-laminarabioside. Molecular dynamics simulations were initiated from all minima. For each disaccharide, the simulation started from the A minimum was conducted for 50 ns, while the other minima were explored for 10 ns. The simulations revealed two stable minima for both compounds. For methyl β-cellobioside, the simulation minima in aqueous solution were shifted from their adiabatic map counterparts, while the simulation minima for methyl β-laminarabioside coincided with the corresponding adiabatic map minima. To validate the simulation results, NMR-derived NOEs and coupling constants across the glycoside linkage, ³J_HC and ³J_CH, were compared with values calculated from the MD trajectories. For each disaccharide, the best agreement was obtained for the simulations started at the A minimum. For both compounds, inter-ring water bridges in combination with the direct hydrogen bonds between the same groups were found to be determining factors for the overall solution structure of the disaccharides which differed from solid-state structures. Comparison with helical parameters showed that the preferred glycosidic dihedral configurations in the methyl β-cellobioside simulation were not highly compatible with the structure of cellulose, but that curdlan helix structures agreed relatively well with the methyl β-laminarabioside simulation. Polymers generated using glycosidic dihedral angles from the simulations revealed secondary structure motifs that that may help to elucidate polymer associations and small-molecule binding.

Original language	English
Journal	Carbohydrate Research
Volume	345
Issue number	4
Pages (from-to)	474-486
Number of pages	13
ISSN	0008-6215
DOIs	https://doi.org/10.1016/j.carres.2009.12.009
Publication status	Published - 26 Feb 2010

Access to Document

10.1016/j.carres.2009.12.009

Cite this

Christensen, N. J., Hansen, P. I., Larsen, F. H., Folkerman, T., Motawie, M. S., & Engelsen, S. B. (2010). A combined nuclear magnetic resonance and molecular dynamics study of the two structural motifs for mixed-linkage ß-glucans: methyl ß-cellobioside and methyl ß-laminarabioside. Carbohydrate Research, 345(4), 474-486. https://doi.org/10.1016/j.carres.2009.12.009

A combined nuclear magnetic resonance and molecular dynamics study of the two structural motifs for mixed-linkage ß-glucans : methyl ß-cellobioside and methyl ß-laminarabioside. / Christensen, Niels Johan; Hansen, Peter Ibsen; Larsen, Flemming Hofmann et al.

In: Carbohydrate Research, Vol. 345, No. 4, 26.02.2010, p. 474-486.

Research output: Contribution to journal › Journal article › Research › peer-review

@article{1497572587b447c686b5e728be1009e7,

title = "A combined nuclear magnetic resonance and molecular dynamics study of the two structural motifs for mixed-linkage {\ss}-glucans: methyl {\ss}-cellobioside and methyl {\ss}-laminarabioside",

abstract = "The conformational and hydration properties of the two disaccharides methyl β-cellobioside and methyl β-laminarabioside were investigated by NMR spectroscopy and explicit solvation molecular dynamics simulations using the carbohydrate solution force field (CSFF). Adiabatic maps produced with this force field displayed 4 minima A: (Φ = 300°, Ψ = 280°), B: (Φ = 280°, Ψ = 210°), C: (Φ = 260°, Ψ = 60°), and D: (Φ = 60°, Ψ = 260°) for methyl β-cellobioside and 3 minima A: (Φ = 290°, Ψ = 130°), B: (Φ = 270°, Ψ = 290°), and C: (Φ = 60°, Ψ = 120°) for methyl β-laminarabioside. Molecular dynamics simulations were initiated from all minima. For each disaccharide, the simulation started from the A minimum was conducted for 50 ns, while the other minima were explored for 10 ns. The simulations revealed two stable minima for both compounds. For methyl β-cellobioside, the simulation minima in aqueous solution were shifted from their adiabatic map counterparts, while the simulation minima for methyl β-laminarabioside coincided with the corresponding adiabatic map minima. To validate the simulation results, NMR-derived NOEs and coupling constants across the glycoside linkage, 3JHC and 3JCH, were compared with values calculated from the MD trajectories. For each disaccharide, the best agreement was obtained for the simulations started at the A minimum. For both compounds, inter-ring water bridges in combination with the direct hydrogen bonds between the same groups were found to be determining factors for the overall solution structure of the disaccharides which differed from solid-state structures. Comparison with helical parameters showed that the preferred glycosidic dihedral configurations in the methyl β-cellobioside simulation were not highly compatible with the structure of cellulose, but that curdlan helix structures agreed relatively well with the methyl β-laminarabioside simulation. Polymers generated using glycosidic dihedral angles from the simulations revealed secondary structure motifs that that may help to elucidate polymer associations and small-molecule binding.",

author = "Christensen, {Niels Johan} and Hansen, {Peter Ibsen} and Larsen, {Flemming Hofmann} and Tore Folkerman and Motawie, {Mohammed Saddik} and Engelsen, {S{\o}ren Balling}",

year = "2010",

month = feb,

day = "26",

doi = "10.1016/j.carres.2009.12.009",

language = "English",

volume = "345",

pages = "474--486",

journal = "Carbohydrate Research",

issn = "0008-6215",

publisher = "Pergamon Press",

number = "4",

}

TY - JOUR

T1 - A combined nuclear magnetic resonance and molecular dynamics study of the two structural motifs for mixed-linkage ß-glucans

T2 - methyl ß-cellobioside and methyl ß-laminarabioside

AU - Christensen, Niels Johan

AU - Hansen, Peter Ibsen

AU - Larsen, Flemming Hofmann

AU - Folkerman, Tore

AU - Motawie, Mohammed Saddik

AU - Engelsen, Søren Balling

PY - 2010/2/26

Y1 - 2010/2/26

N2 - The conformational and hydration properties of the two disaccharides methyl β-cellobioside and methyl β-laminarabioside were investigated by NMR spectroscopy and explicit solvation molecular dynamics simulations using the carbohydrate solution force field (CSFF). Adiabatic maps produced with this force field displayed 4 minima A: (Φ = 300°, Ψ = 280°), B: (Φ = 280°, Ψ = 210°), C: (Φ = 260°, Ψ = 60°), and D: (Φ = 60°, Ψ = 260°) for methyl β-cellobioside and 3 minima A: (Φ = 290°, Ψ = 130°), B: (Φ = 270°, Ψ = 290°), and C: (Φ = 60°, Ψ = 120°) for methyl β-laminarabioside. Molecular dynamics simulations were initiated from all minima. For each disaccharide, the simulation started from the A minimum was conducted for 50 ns, while the other minima were explored for 10 ns. The simulations revealed two stable minima for both compounds. For methyl β-cellobioside, the simulation minima in aqueous solution were shifted from their adiabatic map counterparts, while the simulation minima for methyl β-laminarabioside coincided with the corresponding adiabatic map minima. To validate the simulation results, NMR-derived NOEs and coupling constants across the glycoside linkage, 3JHC and 3JCH, were compared with values calculated from the MD trajectories. For each disaccharide, the best agreement was obtained for the simulations started at the A minimum. For both compounds, inter-ring water bridges in combination with the direct hydrogen bonds between the same groups were found to be determining factors for the overall solution structure of the disaccharides which differed from solid-state structures. Comparison with helical parameters showed that the preferred glycosidic dihedral configurations in the methyl β-cellobioside simulation were not highly compatible with the structure of cellulose, but that curdlan helix structures agreed relatively well with the methyl β-laminarabioside simulation. Polymers generated using glycosidic dihedral angles from the simulations revealed secondary structure motifs that that may help to elucidate polymer associations and small-molecule binding.

AB - The conformational and hydration properties of the two disaccharides methyl β-cellobioside and methyl β-laminarabioside were investigated by NMR spectroscopy and explicit solvation molecular dynamics simulations using the carbohydrate solution force field (CSFF). Adiabatic maps produced with this force field displayed 4 minima A: (Φ = 300°, Ψ = 280°), B: (Φ = 280°, Ψ = 210°), C: (Φ = 260°, Ψ = 60°), and D: (Φ = 60°, Ψ = 260°) for methyl β-cellobioside and 3 minima A: (Φ = 290°, Ψ = 130°), B: (Φ = 270°, Ψ = 290°), and C: (Φ = 60°, Ψ = 120°) for methyl β-laminarabioside. Molecular dynamics simulations were initiated from all minima. For each disaccharide, the simulation started from the A minimum was conducted for 50 ns, while the other minima were explored for 10 ns. The simulations revealed two stable minima for both compounds. For methyl β-cellobioside, the simulation minima in aqueous solution were shifted from their adiabatic map counterparts, while the simulation minima for methyl β-laminarabioside coincided with the corresponding adiabatic map minima. To validate the simulation results, NMR-derived NOEs and coupling constants across the glycoside linkage, 3JHC and 3JCH, were compared with values calculated from the MD trajectories. For each disaccharide, the best agreement was obtained for the simulations started at the A minimum. For both compounds, inter-ring water bridges in combination with the direct hydrogen bonds between the same groups were found to be determining factors for the overall solution structure of the disaccharides which differed from solid-state structures. Comparison with helical parameters showed that the preferred glycosidic dihedral configurations in the methyl β-cellobioside simulation were not highly compatible with the structure of cellulose, but that curdlan helix structures agreed relatively well with the methyl β-laminarabioside simulation. Polymers generated using glycosidic dihedral angles from the simulations revealed secondary structure motifs that that may help to elucidate polymer associations and small-molecule binding.

U2 - 10.1016/j.carres.2009.12.009

DO - 10.1016/j.carres.2009.12.009

M3 - Journal article

C2 - 20079487

SN - 0008-6215

VL - 345

SP - 474

EP - 486

JO - Carbohydrate Research

JF - Carbohydrate Research

IS - 4

ER -

A combined nuclear magnetic resonance and molecular dynamics study of the two structural motifs for mixed-linkage ß-glucans: methyl ß-cellobioside and methyl ß-laminarabioside

Abstract

Access to Document

Fingerprint

Cite this