Team:British Columbia

From 2012.igem.org

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<p align=center><font face=arial narrow size=4><b>Synthetic Syntrophy</b></font></p><font face=arial narrow>
<p align=center><font face=arial narrow size=4><b>Synthetic Syntrophy</b></font></p><font face=arial narrow>
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The field of synthetic biology has seen the development of many biological monocultures capable of performing a wide range of novel functions. In contrast to this current paradigm, microbes have naturally evolved to survive as members of dynamic communities with distributed metabolism. This “divide and conquer” strategy allows the community to perform more complicated metabolic processing than would be possible in single microorganisms while being resilient to environmental changes. Despite very recent proof of concepts in developing model microbial consortia, or synthetic ecology, questions remain as to whether complex metabolic pathways can be engineered in context of microbial populations. The 2012 University of British Columbia iGEM team sets a precedent by engineering a tunable consortium with a distributed 4S desulfurization pathway for increased efficiency in the removal of organosulfurs in heavy oils and bitumen resources.</div>
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The field of synthetic biology has seen the development of many biological monocultures capable of performing a wide range of novel functions. In contrast to this current paradigm, microbes have naturally evolved to survive as members of dynamic communities with distributed metabolism. This “divide and conquer” strategy allows the community to perform more complicated metabolic processing than would be possible in single microorganisms while being resilient to environmental changes. Despite very recent proof of concepts in developing model microbial consortia, or synthetic ecology, questions remain as to whether complex metabolic pathways can be engineered in context of microbial populations. The 2012 University of British Columbia iGEM team sets a precedent by engineering a tunable consortium with a distributed 4S desulfurization pathway for increased efficiency in the removal of organosulfurs in heavy oils and bitumen resources.</br></br></br>
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<p align=center><font face=arial narrow size=4><b>Foundational Advance: Engineering Microbial Consortia</b></font></p><font face=arial narrow>
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<div id=slide><img src="https://static.igem.org/mediawiki/2012/6/66/Ubcigemslide1.jpg"></div>
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<div id=caption></br></br>Synthetic biologists have created systems for bio-sensing, bio-degradation, bio-transformation and bio-synthesis.</div>
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Revision as of 17:16, 29 September 2012

British Columbia - 2012.igem.org


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UBC iGEM 2012 notebook

Synthetic Syntrophy

The field of synthetic biology has seen the development of many biological monocultures capable of performing a wide range of novel functions. In contrast to this current paradigm, microbes have naturally evolved to survive as members of dynamic communities with distributed metabolism. This “divide and conquer” strategy allows the community to perform more complicated metabolic processing than would be possible in single microorganisms while being resilient to environmental changes. Despite very recent proof of concepts in developing model microbial consortia, or synthetic ecology, questions remain as to whether complex metabolic pathways can be engineered in context of microbial populations. The 2012 University of British Columbia iGEM team sets a precedent by engineering a tunable consortium with a distributed 4S desulfurization pathway for increased efficiency in the removal of organosulfurs in heavy oils and bitumen resources.


Foundational Advance: Engineering Microbial Consortia



Synthetic biologists have created systems for bio-sensing, bio-degradation, bio-transformation and bio-synthesis.