Inferring causal metabolic signals that regulate the dynamic TORC1-dependent transcriptome

Ana Paula Oliveira; Sotiris Dimopoulos; Alberto Giovanni Busetto; Stefan Christen; Reinhard Dechant; Laura Falter; Morteza Haghir Chehreghani; Szymon Jozefczuk; Christina Ludwig; Florian Rudroff; Juliane Caroline Schulz; Asier Gonzalez; Alexandre Soulard; Daniele Stracka; Ruedi Aebersold; Joachim M. Buhmann; Michael N. Hall; Matthias Peter; Uwe Sauer; Joerg Stelling

doi:10.15252/MSB.20145475

Inferring causal metabolic signals that regulate the dynamic TORC1-dependent transcriptome

Ana Paula Oliveira, Sotiris Dimopoulos, Alberto Giovanni Busetto, Stefan Christen, Reinhard Dechant, Laura Falter, Morteza Haghir Chehreghani, Szymon Jozefczuk, Christina Ludwig, Florian Rudroff, Juliane Caroline Schulz, Asier Gonzalez, Alexandre Soulard, Daniele Stracka, Ruedi Aebersold, Joachim M. Buhmann, Michael N. Hall, Matthias Peter, Uwe Sauer, Joerg Stelling

Departament de Bioquímica i de Biologia Molecular

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Cells react to nutritional cues in changing environments via the integrated action of signaling, transcriptional, and metabolic networks. Mechanistic insight into signaling processes is often complicated because ubiquitous feedback loops obscure causal relationships. Consequently, the endogenous inputs of many nutrient signaling pathways remain unknown. Recent advances for system‐wide experimental data generation have facilitated the quantification of signaling systems, but the integration of multi‐level dynamic data remains challenging. Here, we co‐designed dynamic experiments and a probabilistic, model‐based method to infer causal relationships between metabolism, signaling, and gene regulation. We analyzed the dynamic regulation of nitrogen metabolism by the target of rapamycin complex 1 (TORC1) pathway in budding yeast. Dynamic transcriptomic, proteomic, and metabolomic measurements along shifts in nitrogen quality yielded a consistent dataset that demonstrated extensive re‐wiring of cellular networks during adaptation. Our inference method identified putative downstream targets of TORC1 and putative metabolic inputs of TORC1, including the hypothesized glutamine signal. The work provides a basis for further mechanistic studies of nitrogen metabolism and a general computational framework to study cellular processes

Idioma original	Anglès
Número d’article	802
Nombre de pàgines	15
Revista	Molecular Systems Biology
Volum	11
Número	4
DOIs	https://doi.org/10.15252/MSB.20145475
Estat de la publicació	Publicada - 2015

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Oliveira, A. P., Dimopoulos, S., Busetto, A. G., Christen, S., Dechant, R., Falter, L., Chehreghani, M. H., Jozefczuk, S., Ludwig, C., Rudroff, F., Schulz, J. C., Gonzalez, A., Soulard, A., Stracka, D., Aebersold, R., Buhmann, J. M., Hall, M. N., Peter, M., Sauer, U., & Stelling, J. (2015). Inferring causal metabolic signals that regulate the dynamic TORC1-dependent transcriptome. Molecular Systems Biology, 11(4), Article 802. https://doi.org/10.15252/MSB.20145475

@article{107f5734c1c946fe9d74a084ad41cd4e,

title = "Inferring causal metabolic signals that regulate the dynamic TORC1-dependent transcriptome",

abstract = "Cells react to nutritional cues in changing environments via the integrated action of signaling, transcriptional, and metabolic networks. Mechanistic insight into signaling processes is often complicated because ubiquitous feedback loops obscure causal relationships. Consequently, the endogenous inputs of many nutrient signaling pathways remain unknown. Recent advances for system‐wide experimental data generation have facilitated the quantification of signaling systems, but the integration of multi‐level dynamic data remains challenging. Here, we co‐designed dynamic experiments and a probabilistic, model‐based method to infer causal relationships between metabolism, signaling, and gene regulation. We analyzed the dynamic regulation of nitrogen metabolism by the target of rapamycin complex 1 (TORC1) pathway in budding yeast. Dynamic transcriptomic, proteomic, and metabolomic measurements along shifts in nitrogen quality yielded a consistent dataset that demonstrated extensive re‐wiring of cellular networks during adaptation. Our inference method identified putative downstream targets of TORC1 and putative metabolic inputs of TORC1, including the hypothesized glutamine signal. The work provides a basis for further mechanistic studies of nitrogen metabolism and a general computational framework to study cellular processes",

author = "Oliveira, \{Ana Paula\} and Sotiris Dimopoulos and Busetto, \{Alberto Giovanni\} and Stefan Christen and Reinhard Dechant and Laura Falter and Chehreghani, \{Morteza Haghir\} and Szymon Jozefczuk and Christina Ludwig and Florian Rudroff and Schulz, \{Juliane Caroline\} and Asier Gonzalez and Alexandre Soulard and Daniele Stracka and Ruedi Aebersold and Buhmann, \{Joachim M.\} and Hall, \{Michael N.\} and Matthias Peter and Uwe Sauer and Joerg Stelling",

year = "2015",

doi = "10.15252/MSB.20145475",

language = "English",

volume = "11",

journal = "Molecular Systems Biology",

issn = "1744-4292",

publisher = "Springer Science and Business Media Deutschland GmbH",

number = "4",

}

Oliveira, AP, Dimopoulos, S, Busetto, AG, Christen, S, Dechant, R, Falter, L, Chehreghani, MH, Jozefczuk, S, Ludwig, C, Rudroff, F, Schulz, JC, Gonzalez, A, Soulard, A, Stracka, D, Aebersold, R, Buhmann, JM, Hall, MN, Peter, M, Sauer, U & Stelling, J 2015, 'Inferring causal metabolic signals that regulate the dynamic TORC1-dependent transcriptome', Molecular Systems Biology, vol. 11, núm. 4, 802. https://doi.org/10.15252/MSB.20145475

TY - JOUR

T1 - Inferring causal metabolic signals that regulate the dynamic TORC1-dependent transcriptome

AU - Oliveira, Ana Paula

AU - Dimopoulos, Sotiris

AU - Busetto, Alberto Giovanni

AU - Christen, Stefan

AU - Dechant, Reinhard

AU - Falter, Laura

AU - Chehreghani, Morteza Haghir

AU - Jozefczuk, Szymon

AU - Ludwig, Christina

AU - Rudroff, Florian

AU - Schulz, Juliane Caroline

AU - Gonzalez, Asier

AU - Soulard, Alexandre

AU - Stracka, Daniele

AU - Aebersold, Ruedi

AU - Buhmann, Joachim M.

AU - Hall, Michael N.

AU - Peter, Matthias

AU - Sauer, Uwe

AU - Stelling, Joerg

PY - 2015

Y1 - 2015

N2 - Cells react to nutritional cues in changing environments via the integrated action of signaling, transcriptional, and metabolic networks. Mechanistic insight into signaling processes is often complicated because ubiquitous feedback loops obscure causal relationships. Consequently, the endogenous inputs of many nutrient signaling pathways remain unknown. Recent advances for system‐wide experimental data generation have facilitated the quantification of signaling systems, but the integration of multi‐level dynamic data remains challenging. Here, we co‐designed dynamic experiments and a probabilistic, model‐based method to infer causal relationships between metabolism, signaling, and gene regulation. We analyzed the dynamic regulation of nitrogen metabolism by the target of rapamycin complex 1 (TORC1) pathway in budding yeast. Dynamic transcriptomic, proteomic, and metabolomic measurements along shifts in nitrogen quality yielded a consistent dataset that demonstrated extensive re‐wiring of cellular networks during adaptation. Our inference method identified putative downstream targets of TORC1 and putative metabolic inputs of TORC1, including the hypothesized glutamine signal. The work provides a basis for further mechanistic studies of nitrogen metabolism and a general computational framework to study cellular processes

AB - Cells react to nutritional cues in changing environments via the integrated action of signaling, transcriptional, and metabolic networks. Mechanistic insight into signaling processes is often complicated because ubiquitous feedback loops obscure causal relationships. Consequently, the endogenous inputs of many nutrient signaling pathways remain unknown. Recent advances for system‐wide experimental data generation have facilitated the quantification of signaling systems, but the integration of multi‐level dynamic data remains challenging. Here, we co‐designed dynamic experiments and a probabilistic, model‐based method to infer causal relationships between metabolism, signaling, and gene regulation. We analyzed the dynamic regulation of nitrogen metabolism by the target of rapamycin complex 1 (TORC1) pathway in budding yeast. Dynamic transcriptomic, proteomic, and metabolomic measurements along shifts in nitrogen quality yielded a consistent dataset that demonstrated extensive re‐wiring of cellular networks during adaptation. Our inference method identified putative downstream targets of TORC1 and putative metabolic inputs of TORC1, including the hypothesized glutamine signal. The work provides a basis for further mechanistic studies of nitrogen metabolism and a general computational framework to study cellular processes

UR - https://publons.com/wos-op/publon/4638475/

UR - https://www.scopus.com/pages/publications/84928720415

U2 - 10.15252/MSB.20145475

DO - 10.15252/MSB.20145475

M3 - Article

SN - 1744-4292

VL - 11

JO - Molecular Systems Biology

JF - Molecular Systems Biology

IS - 4

M1 - 802

ER -

Inferring causal metabolic signals that regulate the dynamic TORC1-dependent transcriptome

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