3241
Comment: Updated News
|
5120
|
Deletions are marked like this. | Additions are marked like this. |
Line 4: | Line 4: |
=== Meeting news === '''Metabolic Pathway Analysis 2013''' will be held in Oxford, 16-20 September. See its [[http://www.accliphot.eu/mpa-2013/|website]] for details. |
== News == == International Study Group for Systems Biology 2020 == . This was held on 10-12 September as a hybrid online-physical meeting. Some information is given on the [[https://site.uit.no/isgsb/|current ISGSB site]]. == Understanding the Control of Metabolism == . David Fell's 1997 book is now available via !ResearchGate. |
Line 7: | Line 12: |
=== Vacancy === Postdoctoral research assistant post available; see [[Vacancies]] for details ----- '''New paper online ahead of print:''' Maurice Cheung et al, A method for accounting for maintenance costs in flux balance analysis improves the prediction of plant cell metabolic phenotypes under stress conditions. The Plant Journal .[[http://onlinelibrary.wiley.com/doi/10.1111/tpj.12252/abstract|accepted manuscript]] |
== Latest papers: == 1. Noemi Tejera, Lisa Crossman, Bruce Pearson, Emily Stoakes, Fauzy Nasher, Bilal Djeghout, Mark Poolman, John Wain, Dipali Singh. ''Genome-scale metabolic model driven design of a defined medium for ''Campylobacter jejuni'' M1cam. ''Frontiers in Microbiology, '''11, '''1072 (2020). https://doi.org/10.3389/fmicb.2020.01072 1. Thea SB Møller, Gang Liu, Hassan B Hartman, Martin H Rau, Sisse Mortensen, Kristian Thamsborg, Andreas E Johansen, Morten OA Sommer, Luca Guardabassi, Mark G Poolman, John E Olsen. ''Global responses to oxytetracycline treatment in tetracycline-resistant ''Escherichia coli. Sci Rep '''10, '''8438 (2020). https://doi.org/10.1038/s41598-020-64995-1 1. Lieven, C., Beber, M.E., Olivier, B.G., Poolman M.G ''et al.'' ''MEMOTE for standardized genome-scale metabolic model testing.'' Nat Biotechnol '''38, '''272–276 (2020). https://doi.org/10.1038/s41587-020-0446-y |
Line 12: | Line 17: |
'''Previous paper: '''Mark G. Poolman, Sudip Kundu, Rahul Shaw and David A Fell. Responses to Light Intensity in a Genome–Scale Model of Rice Metabolism. ''Plant Physiology'', 162, 1060-1072, 2013, [[./Publications/articles|PDF]] available. [ [[http://dx.doi.org/10.1104/pp.113.216762|DOI: 10.1104/pp.113.216762]] ] ----- |
== Previous papers: == * Woodfield, Helen; Fenyk, Stepan; Wallington, Emma; Bates, Ruth; Brown, Alexander; Guschina, Irina; Marillia, Elizabeth; Taylor, David; Fell, David; Harwood, John; Fawcett, Tony. ''Increase in lysophosphatidate acyltransferase activity in oilseed rape (Brassica napus L.) increases seed triacylglycerol content despite its low intrinsic flux control coefficient. '' New Phytologist, 224, 700-711 (2019). https://doi.org/10.1111/nph.16100 * Rupert O. J. Norman, Thomas Millat, Sarah Schatschneider, Anne M. Henstra, Ronja Breitkopf, Bart Pander, Florence J. Annan, Pawel Piatek, Hassan B. Hartman, Mark G. Poolman, David A.Fell, Klaus Winzer, Nigel P. Minton and Charlie Hodgman. ''A genome-scale model of ''Clostridium autoethanogenum'' reveals optimal bioprocess conditions for .high-value chemical production from carbon monoxide. ''Engineering Biology, 3:32 (2019). [[http://ietdl.org/t/gbNTm|Open Access]] https://doi.org/10.1049/enb.2018.5003 * Pfau, Christian, Masakapalli, Poolman, Sweetlove & Ebenhoe. ''The intertwined metabolism during symbiotic nitrogen fixation elucidated by metabolic modelling. ''Nature Scientific Reports, 8:12504(2018) https://www.nature.com/articles/s41598-018-30884-x [[https://doi.org/10.1038/s41598-018-30884-x|DOI]] * Zia Fatma, Hassan Hartman, Mark G. Poolman, David A. Fell, Shireesh Srivastava , Tabinda Shakeela and Syed Shams Yazdani. ''Model-assisted metabolic engineering of Escherichia coli for long chain alkane and alcohol production'', Metabolic Engineering, 45, 134-141 (2018). [[https://doi.org/10.1016/j.ymben.2018.01.002|DOI]] |
Line 15: | Line 24: |
Our '''group''' began nearly thirty years ago with initial interests in computer simulation of metabolism and the theoretical analysis of metabolic control and regulation. Whilst these still remain areas of interest, we have since developed interests in modelling signal transduction, in various different approaches to network analysis of metabolism, and in reconstructing metabolic networks from genomic data. In the course of this research, we have addressed problems in microbial, plant and mammalian metabolism, often in conjunction with collaborators who have contributed experimental results. | . Our '''group''' began nearly forty years ago with initial interests in computer simulation of metabolism and the theoretical analysis of metabolic control and regulation. Whilst these still remain areas of interest, we have since developed interests in modelling signal transduction, in various different approaches to network analysis of metabolism, and in reconstructing metabolic networks from genomic data. In the course of this research, we have addressed problems in microbial, plant and mammalian metabolism, often in conjunction with collaborators who have contributed experimental results. |
Line 17: | Line 26: |
Our current work centres on modelling the networks of reactions in cells, with particular emphasis on metabolism. It forms part of the emerging field of Systems Biology, in that we are concerned with understanding how biological function arises from the interactions between many components, and with building predictive models. We have to develop and apply suitable theoretical tools, including metabolic control analysis, computer simulation and other forms of algebraic and numerical analysis. In addition, we are investigating how to decipher the metabolic information contained in genome sequences. We are involved in projects on microbial, plant and animal metabolism, each in collaboration with an experimental team. | . Our current work centres on modelling the networks of reactions in cells, with particular emphasis on metabolism. It forms part of the emerging field of Systems Biology, in that we are concerned with understanding how biological function arises from the interactions between many components, and with building predictive models. We have to develop and apply suitable theoretical tools, including metabolic control analysis, computer simulation and other forms of algebraic and numerical analysis. In addition, we are investigating how to decipher the metabolic information contained in genome sequences. We are involved in projects on microbial, plant and animal metabolism, each in collaboration with an experimental team. |
Line 19: | Line 28: |
Potential applications of our work include the design of changes in cellular metabolism to improve the output of product such as antibiotics, detecting vulnerable sites in cellular networks that could be targets for drugs to control disease-causing organisms, and improved understanding of how organisms manage to adjust their metabolism in response to environmental changes and other signals. | . Potential applications of our work include the design of changes in cellular metabolism to improve the output of product such as antibiotics, detecting vulnerable sites in cellular networks that could be targets for drugs to control disease-causing organisms, and improved understanding of how organisms manage to adjust their metabolism in response to environmental changes and other signals. |
Line 23: | Line 32: |
We also host the following web sites related to our research: | We also used to host the following web sites related to our research, but these are currently off-line.: |
Line 25: | Line 34: |
* [[http://sysbio.brookes.ac.uk|The website of the International Study Group for Systems Biology]] |
* The former website of the International Study Group for Systems Biology (at ://sysbio.brookes.ac.uk) |
Line 28: | Line 36: |
* [[http://mpa.brookes.ac.uk|The website for the Metabolic Pathways Analysis series of meetings]] * [[http://mitoscop.brookes.ac.uk|The website for the BBSRC-ANR project MitoScoP]] * [[http://frim.brookes.ac.uk|The website for the EraSysBio+ project Fruit Integrative Modelling]] |
* The website for the Metabolic Pathways Analysis series of meetings (at ://mpa.brookes.ac.uk) |
News
International Study Group for Systems Biology 2020
This was held on 10-12 September as a hybrid online-physical meeting. Some information is given on the current ISGSB site.
Understanding the Control of Metabolism
David Fell's 1997 book is now available via ResearchGate.
Latest papers:
Noemi Tejera, Lisa Crossman, Bruce Pearson, Emily Stoakes, Fauzy Nasher, Bilal Djeghout, Mark Poolman, John Wain, Dipali Singh. Genome-scale metabolic model driven design of a defined medium for Campylobacter jejuni M1cam. Frontiers in Microbiology, 11, 1072 (2020). https://doi.org/10.3389/fmicb.2020.01072
Thea SB Møller, Gang Liu, Hassan B Hartman, Martin H Rau, Sisse Mortensen, Kristian Thamsborg, Andreas E Johansen, Morten OA Sommer, Luca Guardabassi, Mark G Poolman, John E Olsen. Global responses to oxytetracycline treatment in tetracycline-resistant Escherichia coli. Sci Rep 10, 8438 (2020). https://doi.org/10.1038/s41598-020-64995-1
Lieven, C., Beber, M.E., Olivier, B.G., Poolman M.G et al. MEMOTE for standardized genome-scale metabolic model testing. Nat Biotechnol 38, 272–276 (2020). https://doi.org/10.1038/s41587-020-0446-y
Previous papers:
Woodfield, Helen; Fenyk, Stepan; Wallington, Emma; Bates, Ruth; Brown, Alexander; Guschina, Irina; Marillia, Elizabeth; Taylor, David; Fell, David; Harwood, John; Fawcett, Tony. Increase in lysophosphatidate acyltransferase activity in oilseed rape (Brassica napus L.) increases seed triacylglycerol content despite its low intrinsic flux control coefficient. New Phytologist, 224, 700-711 (2019). https://doi.org/10.1111/nph.16100
Rupert O. J. Norman, Thomas Millat, Sarah Schatschneider, Anne M. Henstra, Ronja Breitkopf, Bart Pander, Florence J. Annan, Pawel Piatek, Hassan B. Hartman, Mark G. Poolman, David A.Fell, Klaus Winzer, Nigel P. Minton and Charlie Hodgman. A genome-scale model of Clostridium autoethanogenum reveals optimal bioprocess conditions for .high-value chemical production from carbon monoxide. Engineering Biology, 3:32 (2019). Open Access https://doi.org/10.1049/enb.2018.5003
Pfau, Christian, Masakapalli, Poolman, Sweetlove & Ebenhoe. The intertwined metabolism during symbiotic nitrogen fixation elucidated by metabolic modelling. Nature Scientific Reports, 8:12504(2018) https://www.nature.com/articles/s41598-018-30884-x DOI
Zia Fatma, Hassan Hartman, Mark G. Poolman, David A. Fell, Shireesh Srivastava , Tabinda Shakeela and Syed Shams Yazdani. Model-assisted metabolic engineering of Escherichia coli for long chain alkane and alcohol production, Metabolic Engineering, 45, 134-141 (2018). DOI
Background
Our group began nearly forty years ago with initial interests in computer simulation of metabolism and the theoretical analysis of metabolic control and regulation. Whilst these still remain areas of interest, we have since developed interests in modelling signal transduction, in various different approaches to network analysis of metabolism, and in reconstructing metabolic networks from genomic data. In the course of this research, we have addressed problems in microbial, plant and mammalian metabolism, often in conjunction with collaborators who have contributed experimental results.
- Our current work centres on modelling the networks of reactions in cells, with particular emphasis on metabolism. It forms part of the emerging field of Systems Biology, in that we are concerned with understanding how biological function arises from the interactions between many components, and with building predictive models. We have to develop and apply suitable theoretical tools, including metabolic control analysis, computer simulation and other forms of algebraic and numerical analysis. In addition, we are investigating how to decipher the metabolic information contained in genome sequences. We are involved in projects on microbial, plant and animal metabolism, each in collaboration with an experimental team.
- Potential applications of our work include the design of changes in cellular metabolism to improve the output of product such as antibiotics, detecting vulnerable sites in cellular networks that could be targets for drugs to control disease-causing organisms, and improved understanding of how organisms manage to adjust their metabolism in response to environmental changes and other signals.
Related Sites
We also used to host the following web sites related to our research, but these are currently off-line.:
- The former website of the International Study Group for Systems Biology (at ://sysbio.brookes.ac.uk)
- The website for the Metabolic Pathways Analysis series of meetings (at ://mpa.brookes.ac.uk)