Difference between revisions of "Team:British Columbia"

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<h2><strong>Using one of nature's strongest molecules for biosynthesis</strong></h2>
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<h2><strong>Harnessing microbial teamwork to degrade and valorize lignocellulosic biomass</strong></h2>
<p>Lignocellulosic biomass is nature's greatest raw reserve of carbon for biosynthesis.</p>
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<p>Development of modern biorefining processes is required to reduce our reliance on petroleum-derived chemicals and fuels. One solution has been to use microbial catalysts to transform renewable biomass into bio-equivalent chemicals.</p>
 
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<p>Serving as the structural support for plant cell walls, lignocellulose is an extremely strong polymer, evolved to resist degradation.</p>
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<p>However, a major obstacle to implementing inductrial-scale bioprocesses is the high cost of processing raw biomass into a usable form. Plant biomass, called lignocellulose, is an abundant and extremely strong polymer that has evolved to resist degradation. Inefficiencies with product yield are inevitably incurred as a consequence of the metabolic strain experienced by single microbial strains that comprise most modern bioprocessing systems. </p>
<p>Sugars locked in the lignocellulose polymer could be used in new and existing biosynthesis pathways to create useful chemicals,materials and biofuels.</p>
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<p>This year, our team aimed to make the processing and utilization of renewable biomass feedstocks cheaper and more efficient by building a microbial community able to transform biomass into useful products.</p>
 
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<h1 style="text-align: center"><big>Crescentium</big></h1>
 
<h1 style="text-align: center"><big>Crescentium</big></h1>
 
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<p style="text-align: center">A flexible closed system bacterial community for the direct conversion of lignocellulosic biomass into valued biosynthetic chemicals.</p>
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<p style="text-align: center">A “divide and conquer” approach to split the tasks of biomass degradation and valorization between two distinct microbial species, <i>Caulobacter crescentus</i> and <i>Escherichia coli</i>.</p>
 
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Revision as of 00:00, 18 October 2016

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Harnessing microbial teamwork to degrade and valorize lignocellulosic biomass

Development of modern biorefining processes is required to reduce our reliance on petroleum-derived chemicals and fuels. One solution has been to use microbial catalysts to transform renewable biomass into bio-equivalent chemicals.

However, a major obstacle to implementing inductrial-scale bioprocesses is the high cost of processing raw biomass into a usable form. Plant biomass, called lignocellulose, is an abundant and extremely strong polymer that has evolved to resist degradation. Inefficiencies with product yield are inevitably incurred as a consequence of the metabolic strain experienced by single microbial strains that comprise most modern bioprocessing systems.

This year, our team aimed to make the processing and utilization of renewable biomass feedstocks cheaper and more efficient by building a microbial community able to transform biomass into useful products.

Crescentium

A “divide and conquer” approach to split the tasks of biomass degradation and valorization between two distinct microbial species, Caulobacter crescentus and Escherichia coli.

The Bacterial Community

Caulobacter crescentus: The subject of novel research at the University of British Columbia. C. crescentus can be engineered to express functional enzymes fused upon its S-Layer.
Escherichia coli: Easily manipulated and cultivated in the lab, E. coli serves as a perfect host for many biosynthetic pathways that transform glucose.

The Transformation Process

C. crecentus cleaves parts of the lignocellulose molecule, releasing glucose in to the system.

E. coli takes in the glucose and, through biosynthetic pathways, converts it into valued chemicals.