Comparison of reverse-engineering methods using an in Silico network

Diogo Camacho; Paola Vera Licona; Pedro Mendes; Reinhard Laubenbacher

doi:10.1196/annals.1407.006

Comparison of reverse-engineering methods using an in Silico network

Diogo Camacho, Paola Vera Licona, Pedro Mendes, Reinhard Laubenbacher

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

Abstract

The reverse engineering of biochemical networks is a central problem in systems biology. In recent years several methods have been developed for this purpose, using techniques from a variety of fields. A systematic comparison of the different methods is complicated by their widely varying data requirements, making benchmarking difficult. Also, because of the lack of detailed knowledge about most real networks, it is not easy to use experimental data for this purpose. This paper contains a comparison of four reverse-engineering methods using data from a simulated network. The network is sufficiently realistic and complex to include many of the challenges that data from real networks pose. Our results indicate that the two methods based on genetic perturbations of the network outperform the other methods, including dynamic Bayesian networks and a partial correlation method. © 2007 New York Academy of Sciences.

Original language	English
Pages (from-to)	73-89
Number of pages	16
Journal	Annals of the New York Academy of Sciences
Volume	1115
DOIs	https://doi.org/10.1196/annals.1407.006
Publication status	Published - Dec 2007

Keywords

Modeling
Reverse engineering
Simulation
Systems biology

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title = "Comparison of reverse-engineering methods using an in Silico network",

abstract = "The reverse engineering of biochemical networks is a central problem in systems biology. In recent years several methods have been developed for this purpose, using techniques from a variety of fields. A systematic comparison of the different methods is complicated by their widely varying data requirements, making benchmarking difficult. Also, because of the lack of detailed knowledge about most real networks, it is not easy to use experimental data for this purpose. This paper contains a comparison of four reverse-engineering methods using data from a simulated network. The network is sufficiently realistic and complex to include many of the challenges that data from real networks pose. Our results indicate that the two methods based on genetic perturbations of the network outperform the other methods, including dynamic Bayesian networks and a partial correlation method. {\textcopyright} 2007 New York Academy of Sciences.",

keywords = "Modeling, Reverse engineering, Simulation, Systems biology",

author = "Diogo Camacho and Licona, {Paola Vera} and Pedro Mendes and Reinhard Laubenbacher",

note = "R01 GM068947, GM, NIGMS NIH HHS, United States",

year = "2007",

month = dec,

doi = "10.1196/annals.1407.006",

language = "English",

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journal = "Annals of the New York Academy of Sciences",

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T1 - Comparison of reverse-engineering methods using an in Silico network

AU - Camacho, Diogo

AU - Licona, Paola Vera

AU - Mendes, Pedro

AU - Laubenbacher, Reinhard

N1 - R01 GM068947, GM, NIGMS NIH HHS, United States

PY - 2007/12

Y1 - 2007/12

N2 - The reverse engineering of biochemical networks is a central problem in systems biology. In recent years several methods have been developed for this purpose, using techniques from a variety of fields. A systematic comparison of the different methods is complicated by their widely varying data requirements, making benchmarking difficult. Also, because of the lack of detailed knowledge about most real networks, it is not easy to use experimental data for this purpose. This paper contains a comparison of four reverse-engineering methods using data from a simulated network. The network is sufficiently realistic and complex to include many of the challenges that data from real networks pose. Our results indicate that the two methods based on genetic perturbations of the network outperform the other methods, including dynamic Bayesian networks and a partial correlation method. © 2007 New York Academy of Sciences.

AB - The reverse engineering of biochemical networks is a central problem in systems biology. In recent years several methods have been developed for this purpose, using techniques from a variety of fields. A systematic comparison of the different methods is complicated by their widely varying data requirements, making benchmarking difficult. Also, because of the lack of detailed knowledge about most real networks, it is not easy to use experimental data for this purpose. This paper contains a comparison of four reverse-engineering methods using data from a simulated network. The network is sufficiently realistic and complex to include many of the challenges that data from real networks pose. Our results indicate that the two methods based on genetic perturbations of the network outperform the other methods, including dynamic Bayesian networks and a partial correlation method. © 2007 New York Academy of Sciences.

KW - Modeling

KW - Reverse engineering

KW - Simulation

KW - Systems biology

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DO - 10.1196/annals.1407.006

M3 - Article

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VL - 1115

SP - 73

EP - 89

JO - Annals of the New York Academy of Sciences

JF - Annals of the New York Academy of Sciences

ER -

Comparison of reverse-engineering methods using an in Silico network

Abstract

Keywords

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