The evolution and structure prediction of coiled coils across all genomes
The evolution and structure prediction of coiled coils across all genomes
Coiled coils are α-helical interactions found in many natural proteins. Various sequence-based coiled-coil predictors are available, but key issues remain: oligomeric state and protein-protein interface prediction and extension to all genomes. We present SpiriCoil (http://supfam.org/SUPERFAMILY/spiricoil), which is based on a novel approach to the coiled-coil prediction problem for coiled coils that fall into known superfamilies: hundreds of hidden Markov models representing coiled-coil-containing domain families. Using whole domains gives the advantage that sequences flanking the coiled coils help. SpiriCoil performs at least as well as existing methods at detecting coiled coils and significantly advances the state of the art for oligomer state prediction. SpiriCoil has been run on over 16 million sequences, including all completely sequenced genomes (more than 1200), and a resulting Web interface supplies data downloads, alignments, scores, oligomeric state classifications, three-dimensional homology models and visualisation. This has allowed, for the first time, a genomewide analysis of coiled-coil evolution. We found that coiled coils have arisen independently de novo well over a hundred times, and these are observed in 16 different oligomeric states. Coiled coils in almost all oligomeric states were present in the last universal common ancestor of life. The vast majority of occasions that individual coiled coils have arisen de novo were before the last universal common ancestor of life; we do, however, observe scattered instances throughout subsequent evolutionary history, mostly in the formation of the eukaryote superkingdom. Coiled coils do not change their oligomeric state over evolution and did not evolve from the rearrangement of existing helices in proteins; coiled coils were forged in unison with the fold of the whole protein.
Computational Biology, Databases as Topic, Evolution, Molecular, Genome, Models, Molecular, Protein Conformation, Protein Multimerization, Proteins/chemistry, Software
480-93
Rackham, Owen J. L.
8122eb1f-6e9f-4da5-90e1-ce108ccbbcbf
Madera, Martin
b4aa75e7-b011-46fa-b8f0-803ae2afe7e0
Armstrong, Craig T.
6ec753fb-4f61-4fec-a1b8-03d0d6794b12
Vincent, Thomas L.
573bf0a4-b76b-49ef-98fc-46a712f511e2
Woolfson, Derek N.
26efd73a-9c12-498e-98a6-56f6b20a2373
Gough, Julian
019ed039-9fd4-45d6-aa7a-12a8fcf7245c
29 October 2010
Rackham, Owen J. L.
8122eb1f-6e9f-4da5-90e1-ce108ccbbcbf
Madera, Martin
b4aa75e7-b011-46fa-b8f0-803ae2afe7e0
Armstrong, Craig T.
6ec753fb-4f61-4fec-a1b8-03d0d6794b12
Vincent, Thomas L.
573bf0a4-b76b-49ef-98fc-46a712f511e2
Woolfson, Derek N.
26efd73a-9c12-498e-98a6-56f6b20a2373
Gough, Julian
019ed039-9fd4-45d6-aa7a-12a8fcf7245c
Rackham, Owen J. L., Madera, Martin, Armstrong, Craig T., Vincent, Thomas L., Woolfson, Derek N. and Gough, Julian
(2010)
The evolution and structure prediction of coiled coils across all genomes.
Journal of Molecular Biology, 403 (3), .
(doi:10.1016/j.jmb.2010.08.032).
Abstract
Coiled coils are α-helical interactions found in many natural proteins. Various sequence-based coiled-coil predictors are available, but key issues remain: oligomeric state and protein-protein interface prediction and extension to all genomes. We present SpiriCoil (http://supfam.org/SUPERFAMILY/spiricoil), which is based on a novel approach to the coiled-coil prediction problem for coiled coils that fall into known superfamilies: hundreds of hidden Markov models representing coiled-coil-containing domain families. Using whole domains gives the advantage that sequences flanking the coiled coils help. SpiriCoil performs at least as well as existing methods at detecting coiled coils and significantly advances the state of the art for oligomer state prediction. SpiriCoil has been run on over 16 million sequences, including all completely sequenced genomes (more than 1200), and a resulting Web interface supplies data downloads, alignments, scores, oligomeric state classifications, three-dimensional homology models and visualisation. This has allowed, for the first time, a genomewide analysis of coiled-coil evolution. We found that coiled coils have arisen independently de novo well over a hundred times, and these are observed in 16 different oligomeric states. Coiled coils in almost all oligomeric states were present in the last universal common ancestor of life. The vast majority of occasions that individual coiled coils have arisen de novo were before the last universal common ancestor of life; we do, however, observe scattered instances throughout subsequent evolutionary history, mostly in the formation of the eukaryote superkingdom. Coiled coils do not change their oligomeric state over evolution and did not evolve from the rearrangement of existing helices in proteins; coiled coils were forged in unison with the fold of the whole protein.
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Published date: 29 October 2010
Additional Information:
Copyright © 2010 Elsevier Ltd. All rights reserved.
Keywords:
Computational Biology, Databases as Topic, Evolution, Molecular, Genome, Models, Molecular, Protein Conformation, Protein Multimerization, Proteins/chemistry, Software
Identifiers
Local EPrints ID: 446491
URI: http://eprints.soton.ac.uk/id/eprint/446491
ISSN: 0022-2836
PURE UUID: 57e6f7ce-5679-43e0-be5f-997476cc49ef
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Date deposited: 11 Feb 2021 17:33
Last modified: 17 Mar 2024 04:03
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Author:
Martin Madera
Author:
Craig T. Armstrong
Author:
Thomas L. Vincent
Author:
Derek N. Woolfson
Author:
Julian Gough
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