OpenPlant: Difference between revisions
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[[File:OpenPlant Logo.png|700px|thumb|right|The development of new foundational tools and parts will directly contribute to the engineering of new traits in plants, such as: Altered photosynthesis and leaf structure, Carbohydrate engineering to increase quality and yield of target polymers, Engineered pathways for the metabolic engineering of natural products, New forms of symbiosis and nitrogen fixation, Methods for high level production of biomolecules by virus engines.]] | [[File:OpenPlant Logo.png|700px|thumb|right|The development of new foundational tools and parts will directly contribute to the engineering of new traits in plants, such as: Altered photosynthesis and leaf structure, Carbohydrate engineering to increase quality and yield of target polymers, Engineered pathways for the metabolic engineering of natural products, New forms of symbiosis and nitrogen fixation, Methods for high level production of biomolecules by virus engines.]] | ||
[https://en.wikipedia.org/wiki/Synthetic_biology Synthetic Biology] offers the prospect of reprogrammed biological systems for improved and sustainable bioproduction. While early efforts in the field have been directed at microbes, the engineering of plant systems provides even greater potential benefits. In contrast to microbes, plants are already globally cultivated at extremely low cost, harvested on the giga-tonne scale, and routinely used to produce the widest range of biostuffs, from fibres, wood, oils, sugar, fine chemicals, drugs to food. Plants are genetically facile, and GM plants are currently grown on the >100 million hectare scale. Plant systems are ripe for synthetic biology, and any improvement in the ability to reprogram metabolic pathways or plant architecture will have far-reaching consequences. | [https://en.wikipedia.org/wiki/Synthetic_biology Synthetic Biology] offers the prospect of reprogrammed biological systems for improved and sustainable bioproduction. While early efforts in the field have been directed at microbes, the engineering of plant systems provides even greater potential benefits. In contrast to microbes, plants are already globally cultivated at extremely low cost, harvested on the giga-tonne scale, and routinely used to produce the widest range of biostuffs, from fibres, wood, oils, sugar, fine chemicals, drugs to food. Plants are genetically facile, and GM plants are currently grown on the >100 million hectare scale. Plant systems are ripe for synthetic biology, and any improvement in the ability to reprogram metabolic pathways or plant architecture will have far-reaching consequences. | ||
== | [http://openplant.org/ OpenPlant] is a [https://en.wikipedia.org/wiki/Biotechnology_and_Biological_Sciences_Research_Council BBSRC] / [https://en.wikipedia.org/wiki/Engineering_and_Physical_Sciences_Research_Council EPSRC] Synthetic Biology Research Centre, supported by the Research Councils' [http://www.bbsrc.ac.uk/research/programmes-networks/synthetic-biology-growth-programme/ Synthetic Biology for Growth programme]. The initiative promotes interdisciplinary exchange, open technologies for innovation and responsible innovation for sustainable agriculture and conservation. | ||
==Examples of initiatives== | |||
* engineering of biological [[Nitrogen Fixation|nitrogen fixation]] in cereal crops. | |||
* exploring ways of modifying plant roots for improved nitrogen uptake, | |||
* altering soil bacteria for beneficial crop associations and production of synthetic ecologies in agriculture. | |||
* Similar possibilities exist for improving photosynthesis, phosphorus utilization, weed control, and bioproduction of new foods, materials, chemicals, pharmaceuticals, biopolymers and energy. | |||
==Comments (Rasmus)== | |||
* the focus on nitrogen production is very interesting | |||
* How do these initiatives interface with the various open source hardware initiatives (OSE, other)? | |||
* very helpful would be projects about [[duckweed]] or [[azolla]] - plants that are easy to grow as part of an [[Integrated Food and Waste Management System|integrated agriculture system]] (project idea: production of omega-3 fatty acids or nitrogen in duckweed). | |||
==Links== | ==Links== | ||
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[[File:OpenPlantDiagram.001.jpg|800px|thumb|left|Work Package Structure. OpenPlant research aims to: accelerate the development of new tools and methods for plant synthetic biology, provide mechanisms for open exchange of resources, apply these standardised tools to world-leading projects in trait development, facilitate interdisciplinary exchange, discussion and outreach. ]] | [[File:OpenPlantDiagram.001.jpg|800px|thumb|left|'''Work Package Structure.''' OpenPlant research aims to: accelerate the development of new tools and methods for plant synthetic biology, provide mechanisms for open exchange of resources, apply these standardised tools to world-leading projects in trait development, facilitate interdisciplinary exchange, discussion and outreach. ]] | ||
[[Category:Materials]] | [[Category:Materials]] | ||
[[Category:Food and Agriculture]] | [[Category:Food and Agriculture]] | ||
[[Category:Biofuel]] | [[Category:Biofuel]] | ||
Revision as of 14:12, 6 August 2016
The development of new foundational tools and parts will directly contribute to the engineering of new traits in plants, such as: Altered photosynthesis and leaf structure, Carbohydrate engineering to increase quality and yield of target polymers, Engineered pathways for the metabolic engineering of natural products, New forms of symbiosis and nitrogen fixation, Methods for high level production of biomolecules by virus engines.
Synthetic Biology offers the prospect of reprogrammed biological systems for improved and sustainable bioproduction. While early efforts in the field have been directed at microbes, the engineering of plant systems provides even greater potential benefits. In contrast to microbes, plants are already globally cultivated at extremely low cost, harvested on the giga-tonne scale, and routinely used to produce the widest range of biostuffs, from fibres, wood, oils, sugar, fine chemicals, drugs to food. Plants are genetically facile, and GM plants are currently grown on the >100 million hectare scale. Plant systems are ripe for synthetic biology, and any improvement in the ability to reprogram metabolic pathways or plant architecture will have far-reaching consequences.
OpenPlant is a BBSRC / EPSRC Synthetic Biology Research Centre, supported by the Research Councils' Synthetic Biology for Growth programme. The initiative promotes interdisciplinary exchange, open technologies for innovation and responsible innovation for sustainable agriculture and conservation.
Examples of initiatives
- engineering of biological nitrogen fixation in cereal crops.
- exploring ways of modifying plant roots for improved nitrogen uptake,
- altering soil bacteria for beneficial crop associations and production of synthetic ecologies in agriculture.
- Similar possibilities exist for improving photosynthesis, phosphorus utilization, weed control, and bioproduction of new foods, materials, chemicals, pharmaceuticals, biopolymers and energy.
Comments (Rasmus)
- the focus on nitrogen production is very interesting
- How do these initiatives interface with the various open source hardware initiatives (OSE, other)?
- very helpful would be projects about duckweed or azolla - plants that are easy to grow as part of an integrated agriculture system (project idea: production of omega-3 fatty acids or nitrogen in duckweed).
Links
- OpenPlant Website | OpenPlant Blog | Twitter: https://twitter.com/@_OpenPlant
- Open Source Hardware Development Method | Open Source Ecology
Work Package Structure. OpenPlant research aims to: accelerate the development of new tools and methods for plant synthetic biology, provide mechanisms for open exchange of resources, apply these standardised tools to world-leading projects in trait development, facilitate interdisciplinary exchange, discussion and outreach.