Wisdom of crowds for robust gene network inference

Daniel Marbach; James C. Costello; Robert Küffner; Nicole M. Vega; Robert J. Prill; Diogo M. Camacho; Kyle R. Allison; Manolis Kellis; James J. Collins; Andrej Aderhold; Gustavo Stolovitzky; Richard Bonneau; Yukun Chen; Francesca Cordero; Martin Crane; Frank Dondelinger; Mathias Drton; Roberto Esposito; Rina Foygel; Alberto De La Fuente; Jan Gertheiss; Pierre Geurts; Alex Greenfield; Marco Grzegorczyk; Anne Claire Haury; Benjamin Holmes; Torsten Hothorn; Dirk Husmeier; Vân Anh Huynh-Thu; Alexandre Irrthum; Guy Karlebach; Sophie Lèbre; Vincenzo De Leo; Aviv Madar; Subramani Mani; Fantine Mordelet; Harry Ostrer; Zhengyu Ouyang; Ravi Pandya; Tobias Petri; Andrea Pinna; Christopher S. Poultney; Serena Rezny; Heather J. Ruskin; Yvan Saeys; Ron Shamir; Alina Sîrbu; Mingzhou Song; Nicola Soranzo; Alexander Statnikov; Nicci Vega; Paola Vera-Licona; Jean Philippe Vert; Alessia Visconti; Haizhou Wang; Louis Wehenkel; Lukas Windhager; Yang Zhang; Ralf Zimmer

doi:10.1038/nmeth.2016

Wisdom of crowds for robust gene network inference

Daniel Marbach, James C. Costello, Robert Küffner, Nicole M. Vega, Robert J. Prill, Diogo M. Camacho, Kyle R. Allison, Manolis Kellis, James J. Collins, Andrej Aderhold, Gustavo Stolovitzky, Richard Bonneau, Yukun Chen, Francesca Cordero, Martin Crane, Frank Dondelinger, Mathias Drton, Roberto Esposito, Rina Foygel, Alberto De La FuenteJan Gertheiss, Pierre Geurts, Alex Greenfield, Marco Grzegorczyk, Anne Claire Haury, Benjamin Holmes, Torsten Hothorn, Dirk Husmeier, Vân Anh Huynh-Thu, Alexandre Irrthum, Guy Karlebach, Sophie Lèbre, Vincenzo De Leo, Aviv Madar, Subramani Mani, Fantine Mordelet, Harry Ostrer, Zhengyu Ouyang, Ravi Pandya, Tobias Petri, Andrea Pinna, Christopher S. Poultney, Serena Rezny, Heather J. Ruskin, Yvan Saeys, Ron Shamir, Alina Sîrbu, Mingzhou Song, Nicola Soranzo, Alexander Statnikov, Nicci Vega, Paola Vera-Licona, Jean Philippe Vert, Alessia Visconti, Haizhou Wang, Louis Wehenkel, Lukas Windhager, Yang Zhang, Ralf Zimmer

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

1232 Scopus citations

Abstract

Reconstructing gene regulatory networks from high-throughput data is a long-standing challenge. Through the Dialogue on Reverse Engineering Assessment and Methods (DREAM) project, we performed a comprehensive blind assessment of over 30 network inference methods on Escherichia coli, Staphylococcus aureus, Saccharomyces cerevisiae and in silico microarray data. We characterize the performance, data requirements and inherent biases of different inference approaches, and we provide guidelines for algorithm application and development. We observed that no single inference method performs optimally across all data sets. In contrast, integration of predictions from multiple inference methods shows robust and high performance across diverse data sets. We thereby constructed high-confidence networks for E. coli and S. aureus, each comprising ∼1,700 transcriptional interactions at a precision of ∼50%. We experimentally tested 53 previously unobserved regulatory interactions in E. coli, of which 23 (43%) were supported. Our results establish community-based methods as a powerful and robust tool for the inference of transcriptional gene regulatory networks.

Original language	English (US)
Pages (from-to)	796-804
Number of pages	9
Journal	Nature Methods
Volume	9
Issue number	8
DOIs	https://doi.org/10.1038/nmeth.2016
State	Published - Aug 2012
Externally published	Yes

ASJC Scopus subject areas

Biotechnology
Biochemistry
Molecular Biology
Cell Biology

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10.1038/nmeth.2016

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Marbach, D., Costello, J. C., Küffner, R., Vega, N. M., Prill, R. J., Camacho, D. M., Allison, K. R., Kellis, M., Collins, J. J., Aderhold, A., Stolovitzky, G., Bonneau, R., Chen, Y., Cordero, F., Crane, M., Dondelinger, F., Drton, M., Esposito, R., Foygel, R., ... Zimmer, R. (2012). Wisdom of crowds for robust gene network inference. Nature Methods, 9(8), 796-804. https://doi.org/10.1038/nmeth.2016

Marbach, D, Costello, JC, Küffner, R, Vega, NM, Prill, RJ, Camacho, DM, Allison, KR, Kellis, M, Collins, JJ, Aderhold, A, Stolovitzky, G, Bonneau, R, Chen, Y, Cordero, F, Crane, M, Dondelinger, F, Drton, M, Esposito, R, Foygel, R, De La Fuente, A, Gertheiss, J, Geurts, P, Greenfield, A, Grzegorczyk, M, Haury, AC, Holmes, B, Hothorn, T, Husmeier, D, Huynh-Thu, VA, Irrthum, A, Karlebach, G, Lèbre, S, De Leo, V, Madar, A, Mani, S, Mordelet, F, Ostrer, H, Ouyang, Z, Pandya, R, Petri, T, Pinna, A, Poultney, CS, Rezny, S, Ruskin, HJ, Saeys, Y, Shamir, R, Sîrbu, A, Song, M, Soranzo, N, Statnikov, A, Vega, N, Vera-Licona, P, Vert, JP, Visconti, A, Wang, H, Wehenkel, L, Windhager, L, Zhang, Y & Zimmer, R 2012, 'Wisdom of crowds for robust gene network inference', Nature Methods, vol. 9, no. 8, pp. 796-804. https://doi.org/10.1038/nmeth.2016

@article{b13e4f15551342919de38329730d2ce8,

title = "Wisdom of crowds for robust gene network inference",

abstract = "Reconstructing gene regulatory networks from high-throughput data is a long-standing challenge. Through the Dialogue on Reverse Engineering Assessment and Methods (DREAM) project, we performed a comprehensive blind assessment of over 30 network inference methods on Escherichia coli, Staphylococcus aureus, Saccharomyces cerevisiae and in silico microarray data. We characterize the performance, data requirements and inherent biases of different inference approaches, and we provide guidelines for algorithm application and development. We observed that no single inference method performs optimally across all data sets. In contrast, integration of predictions from multiple inference methods shows robust and high performance across diverse data sets. We thereby constructed high-confidence networks for E. coli and S. aureus, each comprising ∼1,700 transcriptional interactions at a precision of ∼50%. We experimentally tested 53 previously unobserved regulatory interactions in E. coli, of which 23 (43%) were supported. Our results establish community-based methods as a powerful and robust tool for the inference of transcriptional gene regulatory networks.",

author = "Daniel Marbach and Costello, {James C.} and Robert K{\"u}ffner and Vega, {Nicole M.} and Prill, {Robert J.} and Camacho, {Diogo M.} and Allison, {Kyle R.} and Manolis Kellis and Collins, {James J.} and Andrej Aderhold and Gustavo Stolovitzky and Richard Bonneau and Yukun Chen and Francesca Cordero and Martin Crane and Frank Dondelinger and Mathias Drton and Roberto Esposito and Rina Foygel and {De La Fuente}, Alberto and Jan Gertheiss and Pierre Geurts and Alex Greenfield and Marco Grzegorczyk and Haury, {Anne Claire} and Benjamin Holmes and Torsten Hothorn and Dirk Husmeier and Huynh-Thu, {V{\^a}n Anh} and Alexandre Irrthum and Guy Karlebach and Sophie L{\`e}bre and {De Leo}, Vincenzo and Aviv Madar and Subramani Mani and Fantine Mordelet and Harry Ostrer and Zhengyu Ouyang and Ravi Pandya and Tobias Petri and Andrea Pinna and Poultney, {Christopher S.} and Serena Rezny and Ruskin, {Heather J.} and Yvan Saeys and Ron Shamir and Alina S{\^i}rbu and Mingzhou Song and Nicola Soranzo and Alexander Statnikov and Nicci Vega and Paola Vera-Licona and Vert, {Jean Philippe} and Alessia Visconti and Haizhou Wang and Louis Wehenkel and Lukas Windhager and Yang Zhang and Ralf Zimmer",

note = "Funding Information: We thank all challenge participants for their invaluable contribution; R. Norel and J. Saez Rodriguez, who participated in different aspects of the organization and scoring of DREAM5; and P. Carr, M. Reich, J. Mesirov and the rest of the GenePattern team for providing software and support. This work was funded by the US National Institutes of Health (NIH) National Centers for Biomedical Computing Roadmap Initiative (U54CA121852), Howard Hughes Medical Institute, NIH Director{\textquoteright}s Pioneer Award DPI OD003644 and a fellowship from the Swiss National Science Foundation to D.M. Challenge participants acknowledge: grants ANR-07-BLAN-0311-03 and ANR-09-BLAN-0051-04 from the French National Research Agency (A.-C.H., P.V.-L., F.M., J.-P.V.); the Interuniversity Attraction Poles Programme (IAP P6/25 BIOMAGNET), initiated by the Belgian State, Science Policy Office, the French Community of Belgium (ARC Biomod) and the European Network of Excellence PASCAL2 (V.A.H.-T., A.I., L.W., Y.S., P.G.); the European Community{\textquoteright}s 7th Framework Program, grant no. HEALTH-F4-2007-200767 for the APO-SYS program, and a doctoral fellowship from the Edmond J. Safra Bioinformatics Program at Tel Aviv University (G.K., R.S.); the Irish Research Council for Science Engineering and Technology for financial support under the EMBARK scheme, and the Irish Centre for High-End Computing for provision of computational facilities and technical support (A. S{\^i}rbu, H.J.R., M.C.); the US National Cancer Institute grant U54CA132383 and US National Science Foundation grant HRD-0420407 (Z.O., Y.Z., H.W., M.S.); and the Sardinian Regional Authorities (A.F., A.P., N.S., V.L.). V.A.H.-T. is recipient of a fellowship from the Fonds pour la formation {\`a} la Recherche dans l′Industrie et dans l′Agriculture (F.R.I.A., Belgium); Y.S. is a postdoctoral fellow of the Fonds voor Wetenschappelijk Onderzoek - Vlaanderen (FWO, Belgium); P.G. is Research Associate of the Fonds National de la Recherche Scientifique (FNRS, Belgium).",

year = "2012",

month = aug,

doi = "10.1038/nmeth.2016",

language = "English (US)",

volume = "9",

pages = "796--804",

journal = "Nature Methods",

issn = "1548-7091",

publisher = "Nature Publishing Group",

number = "8",

}

TY - JOUR

T1 - Wisdom of crowds for robust gene network inference

AU - Marbach, Daniel

AU - Costello, James C.

AU - Küffner, Robert

AU - Vega, Nicole M.

AU - Prill, Robert J.

AU - Camacho, Diogo M.

AU - Allison, Kyle R.

AU - Kellis, Manolis

AU - Collins, James J.

AU - Aderhold, Andrej

AU - Stolovitzky, Gustavo

AU - Bonneau, Richard

AU - Chen, Yukun

AU - Cordero, Francesca

AU - Crane, Martin

AU - Dondelinger, Frank

AU - Drton, Mathias

AU - Esposito, Roberto

AU - Foygel, Rina

AU - De La Fuente, Alberto

AU - Gertheiss, Jan

AU - Geurts, Pierre

AU - Greenfield, Alex

AU - Grzegorczyk, Marco

AU - Haury, Anne Claire

AU - Holmes, Benjamin

AU - Hothorn, Torsten

AU - Husmeier, Dirk

AU - Huynh-Thu, Vân Anh

AU - Irrthum, Alexandre

AU - Karlebach, Guy

AU - Lèbre, Sophie

AU - De Leo, Vincenzo

AU - Madar, Aviv

AU - Mani, Subramani

AU - Mordelet, Fantine

AU - Ostrer, Harry

AU - Ouyang, Zhengyu

AU - Pandya, Ravi

AU - Petri, Tobias

AU - Pinna, Andrea

AU - Poultney, Christopher S.

AU - Rezny, Serena

AU - Ruskin, Heather J.

AU - Saeys, Yvan

AU - Shamir, Ron

AU - Sîrbu, Alina

AU - Song, Mingzhou

AU - Soranzo, Nicola

AU - Statnikov, Alexander

AU - Vega, Nicci

AU - Vera-Licona, Paola

AU - Vert, Jean Philippe

AU - Visconti, Alessia

AU - Wang, Haizhou

AU - Wehenkel, Louis

AU - Windhager, Lukas

AU - Zhang, Yang

AU - Zimmer, Ralf

N1 - Funding Information: We thank all challenge participants for their invaluable contribution; R. Norel and J. Saez Rodriguez, who participated in different aspects of the organization and scoring of DREAM5; and P. Carr, M. Reich, J. Mesirov and the rest of the GenePattern team for providing software and support. This work was funded by the US National Institutes of Health (NIH) National Centers for Biomedical Computing Roadmap Initiative (U54CA121852), Howard Hughes Medical Institute, NIH Director’s Pioneer Award DPI OD003644 and a fellowship from the Swiss National Science Foundation to D.M. Challenge participants acknowledge: grants ANR-07-BLAN-0311-03 and ANR-09-BLAN-0051-04 from the French National Research Agency (A.-C.H., P.V.-L., F.M., J.-P.V.); the Interuniversity Attraction Poles Programme (IAP P6/25 BIOMAGNET), initiated by the Belgian State, Science Policy Office, the French Community of Belgium (ARC Biomod) and the European Network of Excellence PASCAL2 (V.A.H.-T., A.I., L.W., Y.S., P.G.); the European Community’s 7th Framework Program, grant no. HEALTH-F4-2007-200767 for the APO-SYS program, and a doctoral fellowship from the Edmond J. Safra Bioinformatics Program at Tel Aviv University (G.K., R.S.); the Irish Research Council for Science Engineering and Technology for financial support under the EMBARK scheme, and the Irish Centre for High-End Computing for provision of computational facilities and technical support (A. Sîrbu, H.J.R., M.C.); the US National Cancer Institute grant U54CA132383 and US National Science Foundation grant HRD-0420407 (Z.O., Y.Z., H.W., M.S.); and the Sardinian Regional Authorities (A.F., A.P., N.S., V.L.). V.A.H.-T. is recipient of a fellowship from the Fonds pour la formation à la Recherche dans l′Industrie et dans l′Agriculture (F.R.I.A., Belgium); Y.S. is a postdoctoral fellow of the Fonds voor Wetenschappelijk Onderzoek - Vlaanderen (FWO, Belgium); P.G. is Research Associate of the Fonds National de la Recherche Scientifique (FNRS, Belgium).

PY - 2012/8

Y1 - 2012/8

N2 - Reconstructing gene regulatory networks from high-throughput data is a long-standing challenge. Through the Dialogue on Reverse Engineering Assessment and Methods (DREAM) project, we performed a comprehensive blind assessment of over 30 network inference methods on Escherichia coli, Staphylococcus aureus, Saccharomyces cerevisiae and in silico microarray data. We characterize the performance, data requirements and inherent biases of different inference approaches, and we provide guidelines for algorithm application and development. We observed that no single inference method performs optimally across all data sets. In contrast, integration of predictions from multiple inference methods shows robust and high performance across diverse data sets. We thereby constructed high-confidence networks for E. coli and S. aureus, each comprising ∼1,700 transcriptional interactions at a precision of ∼50%. We experimentally tested 53 previously unobserved regulatory interactions in E. coli, of which 23 (43%) were supported. Our results establish community-based methods as a powerful and robust tool for the inference of transcriptional gene regulatory networks.

AB - Reconstructing gene regulatory networks from high-throughput data is a long-standing challenge. Through the Dialogue on Reverse Engineering Assessment and Methods (DREAM) project, we performed a comprehensive blind assessment of over 30 network inference methods on Escherichia coli, Staphylococcus aureus, Saccharomyces cerevisiae and in silico microarray data. We characterize the performance, data requirements and inherent biases of different inference approaches, and we provide guidelines for algorithm application and development. We observed that no single inference method performs optimally across all data sets. In contrast, integration of predictions from multiple inference methods shows robust and high performance across diverse data sets. We thereby constructed high-confidence networks for E. coli and S. aureus, each comprising ∼1,700 transcriptional interactions at a precision of ∼50%. We experimentally tested 53 previously unobserved regulatory interactions in E. coli, of which 23 (43%) were supported. Our results establish community-based methods as a powerful and robust tool for the inference of transcriptional gene regulatory networks.

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JO - Nature Methods

JF - Nature Methods

IS - 8

ER -

Wisdom of crowds for robust gene network inference

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