The silicon trypanosome

Barbara M. Bakker; R. Luise Krauth-Siegel; Christine Clayton; Keith Matthews; Mark Girolami; Hans V. Westerhoff; Paul A M Michels; Rainer Breitling; Michael P. Barrett

doi:10.1017/S0031182010000466

The silicon trypanosome

Barbara M. Bakker, R. Luise Krauth-Siegel, Christine Clayton, Keith Matthews, Mark Girolami, Hans V. Westerhoff, Paul A M Michels, Rainer Breitling, Michael P. Barrett

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

Abstract

African trypanosomes have emerged as promising unicellular model organisms for the next generation of systems biology. They offer unique advantages, due to their relative simplicity, the availability of all standard genomics techniques and a long history of quantitative research. Reproducible cultivation methods exist for morphologically and physiologically distinct life-cycle stages. The genome has been sequenced, and microarrays, RNA-interference and high-accuracy metabolomics are available. Furthermore, the availability of extensive kinetic data on all glycolytic enzymes has led to the early development of a complete, experiment-based dynamic model of an important biochemical pathway. Here we describe the achievements of trypanosome systems biology so far and outline the necessary steps towards the ambitious aim of creating a Silicon Trypanosome, a comprehensive, experiment-based, multi-scale mathematical model of trypanosome physiology. We expect that, in the long run, the quantitative modelling enabled by the Silicon Trypanosome will play a key role in selecting the most suitable targets for developing new anti-parasite drugs. Copyright © 2010 Cambridge University Press.

Original language	English
Pages (from-to)	1333-1341
Number of pages	8
Journal	Parasitology
Volume	137
Issue number	9
DOIs	https://doi.org/10.1017/S0031182010000466 https://doi.org/S0031182010000466 [pii] 10.1017/S0031182010000466 [doi]
Publication status	Published - 6 May 2010

Keywords

differentiation
gene expression
metabolism
Silicon Cell
Trypanosoma brucei

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title = "The silicon trypanosome",

abstract = "African trypanosomes have emerged as promising unicellular model organisms for the next generation of systems biology. They offer unique advantages, due to their relative simplicity, the availability of all standard genomics techniques and a long history of quantitative research. Reproducible cultivation methods exist for morphologically and physiologically distinct life-cycle stages. The genome has been sequenced, and microarrays, RNA-interference and high-accuracy metabolomics are available. Furthermore, the availability of extensive kinetic data on all glycolytic enzymes has led to the early development of a complete, experiment-based dynamic model of an important biochemical pathway. Here we describe the achievements of trypanosome systems biology so far and outline the necessary steps towards the ambitious aim of creating a Silicon Trypanosome, a comprehensive, experiment-based, multi-scale mathematical model of trypanosome physiology. We expect that, in the long run, the quantitative modelling enabled by the Silicon Trypanosome will play a key role in selecting the most suitable targets for developing new anti-parasite drugs. Copyright {\textcopyright} 2010 Cambridge University Press.",

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AU - Bakker, Barbara M.

AU - Krauth-Siegel, R. Luise

AU - Clayton, Christine

AU - Matthews, Keith

AU - Girolami, Mark

AU - Westerhoff, Hans V.

AU - Michels, Paul A M

AU - Breitling, Rainer

AU - Barrett, Michael P.

N1 - Bakker, Barbara M Krauth-Siegel, R Luise Clayton, Christine Matthews, Keith Girolami, Mark Westerhoff, Hans V Michels, Paul A M Breitling, Rainer Barrett, Michael P Biotechnology and Biological Sciences Research Council/United Kingdom Research Support, Non-U.S. Gov't Review England Parasitology Parasitology. 2010 Aug;137(9):1333-41. Epub 2010 May 6.

PY - 2010/5/6

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N2 - African trypanosomes have emerged as promising unicellular model organisms for the next generation of systems biology. They offer unique advantages, due to their relative simplicity, the availability of all standard genomics techniques and a long history of quantitative research. Reproducible cultivation methods exist for morphologically and physiologically distinct life-cycle stages. The genome has been sequenced, and microarrays, RNA-interference and high-accuracy metabolomics are available. Furthermore, the availability of extensive kinetic data on all glycolytic enzymes has led to the early development of a complete, experiment-based dynamic model of an important biochemical pathway. Here we describe the achievements of trypanosome systems biology so far and outline the necessary steps towards the ambitious aim of creating a Silicon Trypanosome, a comprehensive, experiment-based, multi-scale mathematical model of trypanosome physiology. We expect that, in the long run, the quantitative modelling enabled by the Silicon Trypanosome will play a key role in selecting the most suitable targets for developing new anti-parasite drugs. Copyright © 2010 Cambridge University Press.

AB - African trypanosomes have emerged as promising unicellular model organisms for the next generation of systems biology. They offer unique advantages, due to their relative simplicity, the availability of all standard genomics techniques and a long history of quantitative research. Reproducible cultivation methods exist for morphologically and physiologically distinct life-cycle stages. The genome has been sequenced, and microarrays, RNA-interference and high-accuracy metabolomics are available. Furthermore, the availability of extensive kinetic data on all glycolytic enzymes has led to the early development of a complete, experiment-based dynamic model of an important biochemical pathway. Here we describe the achievements of trypanosome systems biology so far and outline the necessary steps towards the ambitious aim of creating a Silicon Trypanosome, a comprehensive, experiment-based, multi-scale mathematical model of trypanosome physiology. We expect that, in the long run, the quantitative modelling enabled by the Silicon Trypanosome will play a key role in selecting the most suitable targets for developing new anti-parasite drugs. Copyright © 2010 Cambridge University Press.

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KW - gene expression

KW - metabolism

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KW - Trypanosoma brucei

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JO - Parasitology

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ER -

The silicon trypanosome

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Keywords

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