The pivotal role of protein phosphorylation in the control of yeast central metabolism
The pivotal role of protein phosphorylation in the control of yeast central metabolism
Protein phosphorylation is the most frequent eukaryotic post-translational modification and can act as either a molecular switch or rheostat for protein functions. The deliberate manipulation of protein phosphorylation has great potential for regulating specific protein functions with surgical precision, rather than the gross effects gained by the over/underexpression or complete deletion of a protein-encoding gene. In order to assess the impact of phosphorylation on central metabolism, and thus its potential for biotechnological and medical exploitation, a compendium of highly confident protein phosphorylation sites (p-sites) for the model organism Saccharomyces cerevisiae has been analyzed together with two more datasets from the fungal pathogen Candida albicans. Our analysis highlights the global properties of the regulation of yeast central metabolism by protein phosphorylation, where almost half of the enzymes involved are subject to this sort of post-translational modification. These phosphorylated enzymes, compared to the nonphosphorylated ones, are more abundant, regulate more reactions, have more protein- protein interactions, and a higher fraction of them are ubiquitinated. The p-sites of metabolic enzymes are also more conserved than the background p-sites, and hundreds of them have the potential for regulating metabolite production. All this integrated information has allowed us to prioritize thousands of p-sites in terms of their potential phenotypic impact. This multi-source compendium should enable the design of future high-throughput (HTP) mutation studies to identify key molecular switches/rheostats for the manipulation of not only the metabolism of yeast, but also that of many other biotechnologically and medically important fungi and eukaryotes.
Comparative phosphoproteomics, Metabolism, Phosphorylation, Yeast
1239-1249
Vlastaridis, Panayotis
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Papakyriakou, Athanasios
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Chaliotis, Anargyros
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Stratikos, Efstratios
85f4a2e4-422a-4dab-a067-f50ea7238c00
Oliver, Stephen G.
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Amoutzias, Grigorios D.
8e00c2c4-7cc3-4a24-bf61-c6e1ce184aef
April 2017
Vlastaridis, Panayotis
f5c0f02f-e5a7-45bf-b5c4-681ecf855ca7
Papakyriakou, Athanasios
939bc8c9-1693-4530-9099-c55772b22f1d
Chaliotis, Anargyros
d8fa113c-a8d1-4b07-94bc-9642f7ede740
Stratikos, Efstratios
85f4a2e4-422a-4dab-a067-f50ea7238c00
Oliver, Stephen G.
c3de796f-4c50-4812-a383-208f23b3cd32
Amoutzias, Grigorios D.
8e00c2c4-7cc3-4a24-bf61-c6e1ce184aef
Vlastaridis, Panayotis, Papakyriakou, Athanasios, Chaliotis, Anargyros, Stratikos, Efstratios, Oliver, Stephen G. and Amoutzias, Grigorios D.
(2017)
The pivotal role of protein phosphorylation in the control of yeast central metabolism.
G3: Genes, Genomes, Genetics, 7 (4), .
(doi:10.1534/g3.116.037218).
Abstract
Protein phosphorylation is the most frequent eukaryotic post-translational modification and can act as either a molecular switch or rheostat for protein functions. The deliberate manipulation of protein phosphorylation has great potential for regulating specific protein functions with surgical precision, rather than the gross effects gained by the over/underexpression or complete deletion of a protein-encoding gene. In order to assess the impact of phosphorylation on central metabolism, and thus its potential for biotechnological and medical exploitation, a compendium of highly confident protein phosphorylation sites (p-sites) for the model organism Saccharomyces cerevisiae has been analyzed together with two more datasets from the fungal pathogen Candida albicans. Our analysis highlights the global properties of the regulation of yeast central metabolism by protein phosphorylation, where almost half of the enzymes involved are subject to this sort of post-translational modification. These phosphorylated enzymes, compared to the nonphosphorylated ones, are more abundant, regulate more reactions, have more protein- protein interactions, and a higher fraction of them are ubiquitinated. The p-sites of metabolic enzymes are also more conserved than the background p-sites, and hundreds of them have the potential for regulating metabolite production. All this integrated information has allowed us to prioritize thousands of p-sites in terms of their potential phenotypic impact. This multi-source compendium should enable the design of future high-throughput (HTP) mutation studies to identify key molecular switches/rheostats for the manipulation of not only the metabolism of yeast, but also that of many other biotechnologically and medically important fungi and eukaryotes.
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Accepted/In Press date: 11 February 2017
e-pub ahead of print date: 3 April 2017
Published date: April 2017
Keywords:
Comparative phosphoproteomics, Metabolism, Phosphorylation, Yeast
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Local EPrints ID: 413362
URI: http://eprints.soton.ac.uk/id/eprint/413362
PURE UUID: 79601594-92e1-44b6-a23d-19113b6ea119
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Date deposited: 22 Aug 2017 16:32
Last modified: 16 Mar 2024 04:28
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Author:
Panayotis Vlastaridis
Author:
Athanasios Papakyriakou
Author:
Anargyros Chaliotis
Author:
Efstratios Stratikos
Author:
Stephen G. Oliver
Author:
Grigorios D. Amoutzias
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