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Team:SDU-Denmark/Tour30
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Heidi.Wille (Talk | contribs) (Created page with "{{:Team:SDU-Denmark/core/header| }} <html> <h2>The production system</h2> <h4>The micro-road to rubber</h4> <p> Natural rubber is a chain of several isoprene molecules. The rubbe...") |
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<h4>The micro-road to rubber</h4> | <h4>The micro-road to rubber</h4> | ||
<p> | <p> | ||
| - | Natural rubber is a chain of several isoprene molecules. The rubber tree has a prenyltransferase | + | Natural rubber is a chain of several isoprene molecules. The rubber tree has a <span class="tooltipLink">prenyltransferase</span> <span class="tooltip"> |
| + | HRT2</span> enzyme, which links molecules of <span class="tooltipLink">IPP</span> <span class="tooltip">Isopentenyl pyrophosphate</span> into the <span class="tooltipLink">isoprene chain</span> <span class="tooltip">natural rubber</span>. To start the extension of the chain, the prenyltransferase needs a <span class="tooltipLink">DMAPP</span> <span class="tooltip">Dimethylallyl pyrophosphate</span> molecule. Thus, in order to produce rubber, the bacteria needs the prenyltranferase, IPP, and DMAPP. | ||
</p><p> | </p><p> | ||
| - | IPP and DMAPP are molecules naturally present in E. coli, produced by the bacteria through the MEP pathway | + | IPP and DMAPP are molecules naturally present in E. coli, produced by the bacteria through the <span class="tooltipLink">MEP pathway.</span> <span class="tooltip">Methylerythritol phosphate pathway</span> The MEP pathway converts molecules of <span class="tooltipLink">GAP</span> <span class="tooltip">Glyceraldehyde-3-phosphate</span> and pyruvate - produced by the degradation of glucose (glycolysis) - into IPP and DMAPP. To increase the amount of IPP and DMAPP available for rubber production, we optimized the MEP pathway by elevating the levels of rate limiting enzymes in the pathway. |
</p><p> | </p><p> | ||
Through gene manipulation, we introduced the prenyltransferase gene from the rubber tree to the genetic code of <span class="specialWord">E. coli</span>. This enables the bacteria to express the prenyltransferase enzyme. Consequently the bacteria should be able to convert sugar into natural rubber through; the glycolysis, the MEP pathway, and the prenyltransferase activity. | Through gene manipulation, we introduced the prenyltransferase gene from the rubber tree to the genetic code of <span class="specialWord">E. coli</span>. This enables the bacteria to express the prenyltransferase enzyme. Consequently the bacteria should be able to convert sugar into natural rubber through; the glycolysis, the MEP pathway, and the prenyltransferase activity. | ||
| - | </p><p> | + | </p> |
| - | Dig deeper to see the specification and models of our system, how we designed it in detail, and what thoughts we have about safety. | + | <br> |
| + | <p> | ||
| + | <b>Dig deeper to see the specification and models of our system, how we designed it in detail, and what thoughts we have about safety. Or FastForward to learn more about the process.</b> | ||
</p> | </p> | ||
</html> | </html> | ||
{{:Team:SDU-Denmark/core/footer}} | {{:Team:SDU-Denmark/core/footer}} | ||
Revision as of 22:23, 26 September 2013
The production system
The micro-road to rubber
Natural rubber is a chain of several isoprene molecules. The rubber tree has a prenyltransferase HRT2 enzyme, which links molecules of IPP Isopentenyl pyrophosphate into the isoprene chain natural rubber. To start the extension of the chain, the prenyltransferase needs a DMAPP Dimethylallyl pyrophosphate molecule. Thus, in order to produce rubber, the bacteria needs the prenyltranferase, IPP, and DMAPP.
IPP and DMAPP are molecules naturally present in E. coli, produced by the bacteria through the MEP pathway. Methylerythritol phosphate pathway The MEP pathway converts molecules of GAP Glyceraldehyde-3-phosphate and pyruvate - produced by the degradation of glucose (glycolysis) - into IPP and DMAPP. To increase the amount of IPP and DMAPP available for rubber production, we optimized the MEP pathway by elevating the levels of rate limiting enzymes in the pathway.
Through gene manipulation, we introduced the prenyltransferase gene from the rubber tree to the genetic code of E. coli. This enables the bacteria to express the prenyltransferase enzyme. Consequently the bacteria should be able to convert sugar into natural rubber through; the glycolysis, the MEP pathway, and the prenyltransferase activity.
Dig deeper to see the specification and models of our system, how we designed it in detail, and what thoughts we have about safety. Or FastForward to learn more about the process.
