Access to Cα backbone dynamics of biological solids by13C T1 Relaxation and molecular dynamics simulation

Sam Asami; Justin R. Porter; Oliver F. Lange; Bernd Reif

doi:10.1021/ja509367q

Access to Cα backbone dynamics of biological solids by¹³C T₁ Relaxation and molecular dynamics simulation

Sam Asami, Justin R. Porter, Oliver F. Lange, Bernd Reif

Associate Professorship of Solid-State NMR spectroscopy

Research output: Contribution to journal › Article › peer-review

31 Scopus citations

Abstract

We introduce a labeling scheme for magic angle spinning (MAS) solid-state NMR that is based on deuteration in combination with dilution of the carbon spin system. The labeling strategy achieves spectral editing by simplification of the HinnodataalphaCinnodataalpha and aliphatic side chain spectral region. A reduction in both proton and carbon spin density in combination with fast spinning (≥50 kHz) is essential to retrieve artifact-free ¹³C-R₁ relaxation data for aliphatic carbons. We obtain good agreement between the NMR experimental data and order parameters extracted from a molecular dynamics (MD) trajectory, which indicates that carbon based relaxation parameters can yield complementary information on protein backbone as well as side chain dynamics. (Graph Presented).

Original language	English
Pages (from-to)	1094-1100
Number of pages	7
Journal	Journal of the American Chemical Society
Volume	137
Issue number	3
DOIs	https://doi.org/10.1021/ja509367q
State	Published - 28 Jan 2015

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title = "Access to Cα backbone dynamics of biological solids by13C T1 Relaxation and molecular dynamics simulation",

abstract = "We introduce a labeling scheme for magic angle spinning (MAS) solid-state NMR that is based on deuteration in combination with dilution of the carbon spin system. The labeling strategy achieves spectral editing by simplification of the HinnodataalphaCinnodataalpha and aliphatic side chain spectral region. A reduction in both proton and carbon spin density in combination with fast spinning (≥50 kHz) is essential to retrieve artifact-free 13C-R1 relaxation data for aliphatic carbons. We obtain good agreement between the NMR experimental data and order parameters extracted from a molecular dynamics (MD) trajectory, which indicates that carbon based relaxation parameters can yield complementary information on protein backbone as well as side chain dynamics. (Graph Presented).",

author = "Sam Asami and Porter, {Justin R.} and Lange, {Oliver F.} and Bernd Reif",

note = "Publisher Copyright: {\textcopyright} 2015 American Chemical Society.",

year = "2015",

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doi = "10.1021/ja509367q",

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T1 - Access to Cα backbone dynamics of biological solids by13C T1 Relaxation and molecular dynamics simulation

AU - Asami, Sam

AU - Porter, Justin R.

AU - Lange, Oliver F.

AU - Reif, Bernd

PY - 2015/1/28

Y1 - 2015/1/28

N2 - We introduce a labeling scheme for magic angle spinning (MAS) solid-state NMR that is based on deuteration in combination with dilution of the carbon spin system. The labeling strategy achieves spectral editing by simplification of the HinnodataalphaCinnodataalpha and aliphatic side chain spectral region. A reduction in both proton and carbon spin density in combination with fast spinning (≥50 kHz) is essential to retrieve artifact-free 13C-R1 relaxation data for aliphatic carbons. We obtain good agreement between the NMR experimental data and order parameters extracted from a molecular dynamics (MD) trajectory, which indicates that carbon based relaxation parameters can yield complementary information on protein backbone as well as side chain dynamics. (Graph Presented).

AB - We introduce a labeling scheme for magic angle spinning (MAS) solid-state NMR that is based on deuteration in combination with dilution of the carbon spin system. The labeling strategy achieves spectral editing by simplification of the HinnodataalphaCinnodataalpha and aliphatic side chain spectral region. A reduction in both proton and carbon spin density in combination with fast spinning (≥50 kHz) is essential to retrieve artifact-free 13C-R1 relaxation data for aliphatic carbons. We obtain good agreement between the NMR experimental data and order parameters extracted from a molecular dynamics (MD) trajectory, which indicates that carbon based relaxation parameters can yield complementary information on protein backbone as well as side chain dynamics. (Graph Presented).

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JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

IS - 3

ER -

Access to Cα backbone dynamics of biological solids by¹³C T₁ Relaxation and molecular dynamics simulation

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