Photosynthetic metabolism of C3 plants shows highly cooperative regulation under changing environments: a systems biological analysis
- Ruoyu Luo,
- Haibin Wei,
- Lin Ye,
- Kankan Wang,
- Fan Chen,
- Lijun Luo
- Shanghai Center for Bioinformation Technology,
- Fudan University,
- Chinese Academy of Sciences,
- Ruijin Hospital,
- Shanghai Agro-Biological Gene Center
Research Output: Contribution to journal Article Peer-review
Open access
Abstract
We studied the robustness of photosynthetic metabolism in the chloroplasts of C3 plants under drought stress and at high CO2 concentration conditions by using a method called Minimization of Metabolic Adjustment Dynamic Flux Balance Analysis (M_DFBA). Photosynthetic metabolism in the chloroplasts of C3 plants applies highly cooperative regulation to minimize the fluctuation of metabolite concentration profiles in the face of transient perturbations. Our work suggests that highly cooperative regulation assures the robustness of the biological system and that there is closer cooperation under perturbation conditions than under normal conditions. This results in minimizing fluctuations in the profiles of metabolite concentrations, which is the key to maintaining a system's function. Our methods help in understanding such phenomena and the mechanisms of robustness for complex metabolic networks in dynamic processes.
Publication Information
Output type
Research Output: Contribution to journal Article Peer-review
Original language
EnglishPages from-to (Number of pages)
Pages 847-852Journal (Volume, Issue Number)
Proceedings of the National Academy of Sciences of the United States of America (Volume 106, Issue 3)Publication milestones
- Published - 20/01/2009
Publication status
Published - 20/01/2009
ISSN
0027-8424External Publication IDs
- handle.net: 10547/225212
- Scopus: 58849110784
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Final published version, 778.94 KB
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