Systematic discovery of in vivo phosphorylation networks.

Claus Jorgensen; Rune Linding; Lars Juhl Jensen; Gerard J Ostheimer; Marcel A T M van Vugt; Claus Jørgensen; Ioana M Miron; Francesca Diella; Karen Colwill; Lorne Taylor; Kelly Elder; Pavel Metalnikov; Vivian Nguyen; Adrian Pasculescu; Jing Jin; Jin Gyoon Park; Leona D Samson; James R Woodgett; Robert B Russell; Peer Bork; Michael B Yaffe; Tony Pawson

doi:10.1016/j.cell.2007.05.052

Systematic discovery of in vivo phosphorylation networks.

Claus Jorgensen, Rune Linding, Lars Juhl Jensen, Gerard J Ostheimer, Marcel A T M van Vugt, Claus Jørgensen, Ioana M Miron, Francesca Diella, Karen Colwill, Lorne Taylor, Kelly Elder, Pavel Metalnikov, Vivian Nguyen, Adrian Pasculescu, Jing Jin, Jin Gyoon Park, Leona D Samson, James R Woodgett, Robert B Russell, Peer BorkMichael B Yaffe, Tony Pawson

Cancer Research UK Manchester Institute

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

Abstract

Protein kinases control cellular decision processes by phosphorylating specific substrates. Thousands of in vivo phosphorylation sites have been identified, mostly by proteome-wide mapping. However, systematically matching these sites to specific kinases is presently infeasible, due to limited specificity of consensus motifs, and the influence of contextual factors, such as protein scaffolds, localization, and expression, on cellular substrate specificity. We have developed an approach (NetworKIN) that augments motif-based predictions with the network context of kinases and phosphoproteins. The latter provides 60%-80% of the computational capability to assign in vivo substrate specificity. NetworKIN pinpoints kinases responsible for specific phosphorylations and yields a 2.5-fold improvement in the accuracy with which phosphorylation networks can be constructed. Applying this approach to DNA damage signaling, we show that 53BP1 and Rad50 are phosphorylated by CDK1 and ATM, respectively. We describe a scalable strategy to evaluate predictions, which suggests that BCLAF1 is a GSK-3 substrate.

Original language	English
Journal	Cell
Volume	129
Issue number	7
DOIs	https://doi.org/10.1016/j.cell.2007.05.052
Publication status	Published - 29 Jun 2007

Research Beacons, Institutes and Platforms

Manchester Cancer Research Centre

Access to Document

10.1016/j.cell.2007.05.052

Cite this

Jorgensen, C., Linding, R., Jensen, L. J., Ostheimer, G. J., van Vugt, M. A. T. M., Jørgensen, C., Miron, I. M., Diella, F., Colwill, K., Taylor, L., Elder, K., Metalnikov, P., Nguyen, V., Pasculescu, A., Jin, J., Park, J. G., Samson, L. D., Woodgett, J. R., Russell, R. B., ... Pawson, T. (2007). Systematic discovery of in vivo phosphorylation networks. Cell, 129(7). https://doi.org/10.1016/j.cell.2007.05.052

@article{23693a05ede14540a1992ccb67234188,

title = "Systematic discovery of in vivo phosphorylation networks.",

abstract = "Protein kinases control cellular decision processes by phosphorylating specific substrates. Thousands of in vivo phosphorylation sites have been identified, mostly by proteome-wide mapping. However, systematically matching these sites to specific kinases is presently infeasible, due to limited specificity of consensus motifs, and the influence of contextual factors, such as protein scaffolds, localization, and expression, on cellular substrate specificity. We have developed an approach (NetworKIN) that augments motif-based predictions with the network context of kinases and phosphoproteins. The latter provides 60%-80% of the computational capability to assign in vivo substrate specificity. NetworKIN pinpoints kinases responsible for specific phosphorylations and yields a 2.5-fold improvement in the accuracy with which phosphorylation networks can be constructed. Applying this approach to DNA damage signaling, we show that 53BP1 and Rad50 are phosphorylated by CDK1 and ATM, respectively. We describe a scalable strategy to evaluate predictions, which suggests that BCLAF1 is a GSK-3 substrate.",

author = "Claus Jorgensen and Rune Linding and Jensen, {Lars Juhl} and Ostheimer, {Gerard J} and {van Vugt}, {Marcel A T M} and Claus J{\o}rgensen and Miron, {Ioana M} and Francesca Diella and Karen Colwill and Lorne Taylor and Kelly Elder and Pavel Metalnikov and Vivian Nguyen and Adrian Pasculescu and Jing Jin and Park, {Jin Gyoon} and Samson, {Leona D} and Woodgett, {James R} and Russell, {Robert B} and Peer Bork and Yaffe, {Michael B} and Tony Pawson",

note = "12043, Canadian Institutes of Health Research, CanadaU54 CA112967, NCI NIH HHS, United StatesU54 CA112967-03, NCI NIH HHS, United StatesU54-CA112967-03, NCI NIH HHS, United States",

year = "2007",

month = jun,

day = "29",

doi = "10.1016/j.cell.2007.05.052",

language = "English",

volume = "129",

journal = "Cell",

issn = "0092-8674",

publisher = "Elsevier BV",

number = "7",

}

Jorgensen, C, Linding, R, Jensen, LJ, Ostheimer, GJ, van Vugt, MATM, Jørgensen, C, Miron, IM, Diella, F, Colwill, K, Taylor, L, Elder, K, Metalnikov, P, Nguyen, V, Pasculescu, A, Jin, J, Park, JG, Samson, LD, Woodgett, JR, Russell, RB, Bork, P, Yaffe, MB & Pawson, T 2007, 'Systematic discovery of in vivo phosphorylation networks.', Cell, vol. 129, no. 7. https://doi.org/10.1016/j.cell.2007.05.052

TY - JOUR

T1 - Systematic discovery of in vivo phosphorylation networks.

AU - Jorgensen, Claus

AU - Linding, Rune

AU - Jensen, Lars Juhl

AU - Ostheimer, Gerard J

AU - van Vugt, Marcel A T M

AU - Jørgensen, Claus

AU - Miron, Ioana M

AU - Diella, Francesca

AU - Colwill, Karen

AU - Taylor, Lorne

AU - Elder, Kelly

AU - Metalnikov, Pavel

AU - Nguyen, Vivian

AU - Pasculescu, Adrian

AU - Jin, Jing

AU - Park, Jin Gyoon

AU - Samson, Leona D

AU - Woodgett, James R

AU - Russell, Robert B

AU - Bork, Peer

AU - Yaffe, Michael B

AU - Pawson, Tony

N1 - 12043, Canadian Institutes of Health Research, CanadaU54 CA112967, NCI NIH HHS, United StatesU54 CA112967-03, NCI NIH HHS, United StatesU54-CA112967-03, NCI NIH HHS, United States

PY - 2007/6/29

Y1 - 2007/6/29

N2 - Protein kinases control cellular decision processes by phosphorylating specific substrates. Thousands of in vivo phosphorylation sites have been identified, mostly by proteome-wide mapping. However, systematically matching these sites to specific kinases is presently infeasible, due to limited specificity of consensus motifs, and the influence of contextual factors, such as protein scaffolds, localization, and expression, on cellular substrate specificity. We have developed an approach (NetworKIN) that augments motif-based predictions with the network context of kinases and phosphoproteins. The latter provides 60%-80% of the computational capability to assign in vivo substrate specificity. NetworKIN pinpoints kinases responsible for specific phosphorylations and yields a 2.5-fold improvement in the accuracy with which phosphorylation networks can be constructed. Applying this approach to DNA damage signaling, we show that 53BP1 and Rad50 are phosphorylated by CDK1 and ATM, respectively. We describe a scalable strategy to evaluate predictions, which suggests that BCLAF1 is a GSK-3 substrate.

AB - Protein kinases control cellular decision processes by phosphorylating specific substrates. Thousands of in vivo phosphorylation sites have been identified, mostly by proteome-wide mapping. However, systematically matching these sites to specific kinases is presently infeasible, due to limited specificity of consensus motifs, and the influence of contextual factors, such as protein scaffolds, localization, and expression, on cellular substrate specificity. We have developed an approach (NetworKIN) that augments motif-based predictions with the network context of kinases and phosphoproteins. The latter provides 60%-80% of the computational capability to assign in vivo substrate specificity. NetworKIN pinpoints kinases responsible for specific phosphorylations and yields a 2.5-fold improvement in the accuracy with which phosphorylation networks can be constructed. Applying this approach to DNA damage signaling, we show that 53BP1 and Rad50 are phosphorylated by CDK1 and ATM, respectively. We describe a scalable strategy to evaluate predictions, which suggests that BCLAF1 is a GSK-3 substrate.

U2 - 10.1016/j.cell.2007.05.052

DO - 10.1016/j.cell.2007.05.052

M3 - Article

C2 - 17570479

SN - 0092-8674

VL - 129

JO - Cell

JF - Cell

IS - 7

ER -

Systematic discovery of in vivo phosphorylation networks.

Abstract

Research Beacons, Institutes and Platforms

Access to Document

Fingerprint

Cite this