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SLiMPrints: conservation-based discovery of functional motif fingerprints in intrinsically disordered protein regions

SLiMPrints: conservation-based discovery of functional motif fingerprints in intrinsically disordered protein regions
SLiMPrints: conservation-based discovery of functional motif fingerprints in intrinsically disordered protein regions
Large portions of higher eukaryotic proteomes are intrinsically disordered, and abundant evidence suggests that these unstructured regions of proteins are rich in regulatory interaction interfaces. A major class of disordered interaction interfaces are the compact and degenerate modules known as short linear motifs (SLiMs). As a result of the difficulties associated with the experimental identification and validation of SLiMs, our understanding of these modules is limited, advocating the use of computational methods to focus experimental discovery. This article evaluates the use of evolutionary conservation as a discriminatory technique for motif discovery. A statistical framework is introduced to assess the significance of relatively conserved residues, quantifying the likelihood a residue will have a particular level of conservation given the conservation of the surrounding residues. The framework is expanded to assess the significance of groupings of conserved residues, a metric that forms the basis of SLiMPrints (short linear motif fingerprints), a de novo motif discovery tool. SLiMPrints identifies relatively overconstrained proximal groupings of residues within intrinsically disordered regions, indicative of putatively functional motifs. Finally, the human proteome is analysed to create a set of highly conserved putative motif instances, including a novel site on translation initiation factor eIF2A that may regulate translation through binding of eIF4E.
0305-1048
10628-10641
Davey, N. E.
52278a5f-a2fc-422a-866e-1e46737c5afe
Cowan, J. L.
a34fc26a-e7a3-435f-85c8-4f196b1c8d63
Shields, D. C.
57ffee4f-0277-4b3d-9c7a-8c328637d8e6
Gibson, T. J.
221ac91f-e4b4-4bc0-93c3-81533e4be820
Coldwell, M. J.
a3432799-ed45-4948-9f7a-2a284d3ec65c
Edwards, R. J.
9d25e74f-dc0d-455a-832c-5f363d864c43
Davey, N. E.
52278a5f-a2fc-422a-866e-1e46737c5afe
Cowan, J. L.
a34fc26a-e7a3-435f-85c8-4f196b1c8d63
Shields, D. C.
57ffee4f-0277-4b3d-9c7a-8c328637d8e6
Gibson, T. J.
221ac91f-e4b4-4bc0-93c3-81533e4be820
Coldwell, M. J.
a3432799-ed45-4948-9f7a-2a284d3ec65c
Edwards, R. J.
9d25e74f-dc0d-455a-832c-5f363d864c43

Davey, N. E., Cowan, J. L., Shields, D. C., Gibson, T. J., Coldwell, M. J. and Edwards, R. J. (2012) SLiMPrints: conservation-based discovery of functional motif fingerprints in intrinsically disordered protein regions. Nucleic Acids Research, 40 (21), 10628-10641. (doi:10.1093/nar/gks854).

Record type: Article

Abstract

Large portions of higher eukaryotic proteomes are intrinsically disordered, and abundant evidence suggests that these unstructured regions of proteins are rich in regulatory interaction interfaces. A major class of disordered interaction interfaces are the compact and degenerate modules known as short linear motifs (SLiMs). As a result of the difficulties associated with the experimental identification and validation of SLiMs, our understanding of these modules is limited, advocating the use of computational methods to focus experimental discovery. This article evaluates the use of evolutionary conservation as a discriminatory technique for motif discovery. A statistical framework is introduced to assess the significance of relatively conserved residues, quantifying the likelihood a residue will have a particular level of conservation given the conservation of the surrounding residues. The framework is expanded to assess the significance of groupings of conserved residues, a metric that forms the basis of SLiMPrints (short linear motif fingerprints), a de novo motif discovery tool. SLiMPrints identifies relatively overconstrained proximal groupings of residues within intrinsically disordered regions, indicative of putatively functional motifs. Finally, the human proteome is analysed to create a set of highly conserved putative motif instances, including a novel site on translation initiation factor eIF2A that may regulate translation through binding of eIF4E.

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Published date: September 2012
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Organisations: Faculty of Natural and Environmental Sciences, Centre for Biological Sciences
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Identifiers

Local EPrints ID: 342948
URI: http://eprints.soton.ac.uk/id/eprint/342948
DOI: doi:10.1093/nar/gks854
ISSN: 0305-1048
PURE UUID: b70d142a-37eb-4818-ab4c-8c222a74d2ac
ORCID for M. J. Coldwell: ORCID iD orcid.org/0000-0002-6243-3886

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Date deposited: 18 Sep 2012 12:52
Last modified: 14 Mar 2024 11:57

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Contributors

Author: N. E. Davey
Author: J. L. Cowan
Author: D. C. Shields
Author: T. J. Gibson
Author: M. J. Coldwell ORCID iD
Author: R. J. Edwards

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