Structural dependencies of protein backbone 2J NC′ couplings

Nenad Juranić; J. J. Dannenberg; Gabriel Cornilescu; Pedro Salvador; Elena Atanasova; Hee Chul Ahn; Slobodan Macura; John L. Markley; Franklyn G. Prendergast

doi:10.1110/ps.073331608

Structural dependencies of protein backbone ²J _NC′ couplings

Nenad Juranić, J. J. Dannenberg, Gabriel Cornilescu, Pedro Salvador, Elena Atanasova, Hee Chul Ahn, Slobodan Macura, John L. Markley, Franklyn G. Prendergast

Department of Pharmacy

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

8 Scopus citations

Abstract

Protein folding can introduce strain in peptide covalent geometry, including deviations from planarity that are difficult to detect, especially for a protein in solution. We have found dependencies in protein backbone ²J_NC′ couplings on the planarity and the relative orientation of the sequential peptide planes. These dependences were observed in experimental ²J_NC′ couplings from seven proteins, and also were supported by DFT calculations for a model tripeptide. Findings indicate that elevated ²J_NC′ couplings may serve as reporters of structural strain in the protein backbone imposed by protein folds. Such information, supplemented with the H-bond strengths derived from ^h3J_NC′ couplings, provides useful insight into the overall energy profile of the protein backbone in solution. Published by Cold Spring Harbor Laboratory Press.

Original language	English
Pages (from-to)	768-776
Number of pages	9
Journal	Protein Science
Volume	17
Issue number	4
DOIs	https://doi.org/10.1110/ps.073331608
State	Published - Apr 2008

Keywords

2JNC′
DFT
H-bond
NMR
Protein structure
Scalar coupling

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title = "Structural dependencies of protein backbone 2J NC′ couplings",

abstract = "Protein folding can introduce strain in peptide covalent geometry, including deviations from planarity that are difficult to detect, especially for a protein in solution. We have found dependencies in protein backbone 2JNC′ couplings on the planarity and the relative orientation of the sequential peptide planes. These dependences were observed in experimental 2JNC′ couplings from seven proteins, and also were supported by DFT calculations for a model tripeptide. Findings indicate that elevated 2JNC′ couplings may serve as reporters of structural strain in the protein backbone imposed by protein folds. Such information, supplemented with the H-bond strengths derived from h3JNC′ couplings, provides useful insight into the overall energy profile of the protein backbone in solution. Published by Cold Spring Harbor Laboratory Press.",

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T1 - Structural dependencies of protein backbone 2J NC′ couplings

AU - Juranić, Nenad

AU - Dannenberg, J. J.

AU - Cornilescu, Gabriel

AU - Salvador, Pedro

AU - Atanasova, Elena

AU - Ahn, Hee Chul

AU - Macura, Slobodan

AU - Markley, John L.

AU - Prendergast, Franklyn G.

PY - 2008/4

Y1 - 2008/4

N2 - Protein folding can introduce strain in peptide covalent geometry, including deviations from planarity that are difficult to detect, especially for a protein in solution. We have found dependencies in protein backbone 2JNC′ couplings on the planarity and the relative orientation of the sequential peptide planes. These dependences were observed in experimental 2JNC′ couplings from seven proteins, and also were supported by DFT calculations for a model tripeptide. Findings indicate that elevated 2JNC′ couplings may serve as reporters of structural strain in the protein backbone imposed by protein folds. Such information, supplemented with the H-bond strengths derived from h3JNC′ couplings, provides useful insight into the overall energy profile of the protein backbone in solution. Published by Cold Spring Harbor Laboratory Press.

AB - Protein folding can introduce strain in peptide covalent geometry, including deviations from planarity that are difficult to detect, especially for a protein in solution. We have found dependencies in protein backbone 2JNC′ couplings on the planarity and the relative orientation of the sequential peptide planes. These dependences were observed in experimental 2JNC′ couplings from seven proteins, and also were supported by DFT calculations for a model tripeptide. Findings indicate that elevated 2JNC′ couplings may serve as reporters of structural strain in the protein backbone imposed by protein folds. Such information, supplemented with the H-bond strengths derived from h3JNC′ couplings, provides useful insight into the overall energy profile of the protein backbone in solution. Published by Cold Spring Harbor Laboratory Press.

KW - 2JNC′

KW - DFT

KW - H-bond

KW - NMR

KW - Protein structure

KW - Scalar coupling

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VL - 17

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JO - Protein Science

JF - Protein Science

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ER -

Structural dependencies of protein backbone ²J _NC′ couplings

Abstract

Keywords

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