Structure determination of a new protein from backbone-centered NMR data and NMR-assisted structure prediction

K. L. Mayer; Y. Qu; S. Bansal; P. D. Leblond; Francis E. Jenney; P. S. Brereton; M. W. Adams; Y. Xu; J. H. Prestegard

Structure determination of a new protein from backbone-centered NMR data and NMR-assisted structure prediction

K. L. Mayer, Y. Qu, S. Bansal, P. D. Leblond, Francis E. Jenney, P. S. Brereton, M. W. Adams, Y. Xu, J. H. Prestegard

Department of Bio-Medical Sciences (PCOM)

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

Abstract

Targeting of proteins for structure determination in structural genomic programs often includes the use of threading and fold recognition methods to exclude proteins belonging to well-populated fold families, but such methods can still fail to recognize preexisting folds. The authors illustrate here a method in which limited amounts of structural data are used to improve an initial homology search and the data are subsequently used to produce a structure by data-constrained refinement of an identified structural template. The data used are primarily NMR-based residual dipolar couplings, but they also include additional chemical shift and backbone-nuclear Overhauser effect data. Using this methodology, a backbone structure was efficiently produced for a 10 kDa protein (PF1455) from Pyrococcus furiosus. Its relationship to existing structures and its probable function are discussed. Â© 2006 Wiley-Liss, Inc.

Original language	American English
Journal	Proteins: Structure, Function and Genetics
Volume	65
State	Published - Jan 1 2006

Keywords

Protein structure prediction
Pyrococcus furiosus
Residual dipolar couplings
Simulated annealing
Structural genomics

Disciplines

Archaea

Cite this

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title = "Structure determination of a new protein from backbone-centered NMR data and NMR-assisted structure prediction",

abstract = " Targeting of proteins for structure determination in structural genomic programs often includes the use of threading and fold recognition methods to exclude proteins belonging to well-populated fold families, but such methods can still fail to recognize preexisting folds. The authors illustrate here a method in which limited amounts of structural data are used to improve an initial homology search and the data are subsequently used to produce a structure by data-constrained refinement of an identified structural template. The data used are primarily NMR-based residual dipolar couplings, but they also include additional chemical shift and backbone-nuclear Overhauser effect data. Using this methodology, a backbone structure was efficiently produced for a 10 kDa protein (PF1455) from Pyrococcus furiosus. Its relationship to existing structures and its probable function are discussed. {\^A}{\textcopyright} 2006 Wiley-Liss, Inc.",

keywords = "Protein structure prediction, Pyrococcus furiosus, Residual dipolar couplings, Simulated annealing, Structural genomics",

author = "Mayer, \{K. L.\} and Y. Qu and S. Bansal and Leblond, \{P. D.\} and Jenney, \{Francis E.\} and Brereton, \{P. S.\} and Adams, \{M. W.\} and Y. Xu and Prestegard, \{J. H.\}",

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language = "American English",

volume = "65",

journal = "Proteins: Structure, Function and Genetics",

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TY - JOUR

T1 - Structure determination of a new protein from backbone-centered NMR data and NMR-assisted structure prediction

AU - Mayer, K. L.

AU - Qu, Y.

AU - Bansal, S.

AU - Leblond, P. D.

AU - Jenney, Francis E.

AU - Brereton, P. S.

AU - Adams, M. W.

AU - Xu, Y.

AU - Prestegard, J. H.

PY - 2006/1/1

Y1 - 2006/1/1

N2 - Targeting of proteins for structure determination in structural genomic programs often includes the use of threading and fold recognition methods to exclude proteins belonging to well-populated fold families, but such methods can still fail to recognize preexisting folds. The authors illustrate here a method in which limited amounts of structural data are used to improve an initial homology search and the data are subsequently used to produce a structure by data-constrained refinement of an identified structural template. The data used are primarily NMR-based residual dipolar couplings, but they also include additional chemical shift and backbone-nuclear Overhauser effect data. Using this methodology, a backbone structure was efficiently produced for a 10 kDa protein (PF1455) from Pyrococcus furiosus. Its relationship to existing structures and its probable function are discussed. Â© 2006 Wiley-Liss, Inc.

AB - Targeting of proteins for structure determination in structural genomic programs often includes the use of threading and fold recognition methods to exclude proteins belonging to well-populated fold families, but such methods can still fail to recognize preexisting folds. The authors illustrate here a method in which limited amounts of structural data are used to improve an initial homology search and the data are subsequently used to produce a structure by data-constrained refinement of an identified structural template. The data used are primarily NMR-based residual dipolar couplings, but they also include additional chemical shift and backbone-nuclear Overhauser effect data. Using this methodology, a backbone structure was efficiently produced for a 10 kDa protein (PF1455) from Pyrococcus furiosus. Its relationship to existing structures and its probable function are discussed. Â© 2006 Wiley-Liss, Inc.

KW - Protein structure prediction

KW - Pyrococcus furiosus

KW - Residual dipolar couplings

KW - Simulated annealing

KW - Structural genomics

UR - https://digitalcommons.pcom.edu/scholarly_papers/599

M3 - Article

VL - 65

JO - Proteins: Structure, Function and Genetics

JF - Proteins: Structure, Function and Genetics

ER -

Structure determination of a new protein from backbone-centered NMR data and NMR-assisted structure prediction

Abstract

Keywords

Disciplines

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