Solvent and conformation dependence of amide i vibrations in peptides and proteins containing proline

Santanu Roy; Joshua Lessing; Georg Meisl; Ziad Ganim; Andrei Tokmakoff; Jasper Knoester; Thomas L.C. Jansen

doi:10.1063/1.3665417

Solvent and conformation dependence of amide i vibrations in peptides and proteins containing proline

Santanu Roy, Joshua Lessing, Georg Meisl, Ziad Ganim, Andrei Tokmakoff, Jasper Knoester, Thomas L.C. Jansen

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

62 Scopus citations

Abstract

We present a mixed quantum-classical model for studying the amide I vibrational dynamics (predominantly CO stretching) in peptides and proteins containing proline. There are existing models developed for determining frequencies of and couplings between the secondary amide units. However, these are not applicable to proline because this amino acid has a tertiary amide unit. Therefore, a new parametrization is required for infrared-spectroscopic studies of proteins that contain proline, such as collagen, the most abundant protein in humans and animals. Here, we construct the electrostatic and dihedral maps accounting for solvent and conformation effects on frequency and coupling for the proline unit. We examine the quality and the applicability of these maps by carrying out spectral simulations of a number of peptides with proline in D ₂O and compare with experimental observations.

Original language	English
Article number	234507
Journal	Journal of Chemical Physics
Volume	135
Issue number	23
DOIs	https://doi.org/10.1063/1.3665417
State	Published - Dec 21 2011
Externally published	Yes

Funding

T.L.C.J. acknowledges the Netherlands Organization for Scientific Research (NWO) for support through a VIDI grant. We thank Sam Gellman for providing the NMR structure of PG12. This work was supported by the National Science Foundation (NSF) (CHE-0911107).

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title = "Solvent and conformation dependence of amide i vibrations in peptides and proteins containing proline",

abstract = "We present a mixed quantum-classical model for studying the amide I vibrational dynamics (predominantly CO stretching) in peptides and proteins containing proline. There are existing models developed for determining frequencies of and couplings between the secondary amide units. However, these are not applicable to proline because this amino acid has a tertiary amide unit. Therefore, a new parametrization is required for infrared-spectroscopic studies of proteins that contain proline, such as collagen, the most abundant protein in humans and animals. Here, we construct the electrostatic and dihedral maps accounting for solvent and conformation effects on frequency and coupling for the proline unit. We examine the quality and the applicability of these maps by carrying out spectral simulations of a number of peptides with proline in D 2O and compare with experimental observations.",

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AU - Roy, Santanu

AU - Lessing, Joshua

AU - Meisl, Georg

AU - Ganim, Ziad

AU - Tokmakoff, Andrei

AU - Knoester, Jasper

AU - Jansen, Thomas L.C.

PY - 2011/12/21

Y1 - 2011/12/21

N2 - We present a mixed quantum-classical model for studying the amide I vibrational dynamics (predominantly CO stretching) in peptides and proteins containing proline. There are existing models developed for determining frequencies of and couplings between the secondary amide units. However, these are not applicable to proline because this amino acid has a tertiary amide unit. Therefore, a new parametrization is required for infrared-spectroscopic studies of proteins that contain proline, such as collagen, the most abundant protein in humans and animals. Here, we construct the electrostatic and dihedral maps accounting for solvent and conformation effects on frequency and coupling for the proline unit. We examine the quality and the applicability of these maps by carrying out spectral simulations of a number of peptides with proline in D 2O and compare with experimental observations.

AB - We present a mixed quantum-classical model for studying the amide I vibrational dynamics (predominantly CO stretching) in peptides and proteins containing proline. There are existing models developed for determining frequencies of and couplings between the secondary amide units. However, these are not applicable to proline because this amino acid has a tertiary amide unit. Therefore, a new parametrization is required for infrared-spectroscopic studies of proteins that contain proline, such as collagen, the most abundant protein in humans and animals. Here, we construct the electrostatic and dihedral maps accounting for solvent and conformation effects on frequency and coupling for the proline unit. We examine the quality and the applicability of these maps by carrying out spectral simulations of a number of peptides with proline in D 2O and compare with experimental observations.

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DO - 10.1063/1.3665417

M3 - Article

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VL - 135

JO - Journal of Chemical Physics

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Solvent and conformation dependence of amide i vibrations in peptides and proteins containing proline

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