Difference between revisions of "Team:Aachen/InteractiveTour31"
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{{Team:Aachen/Header}} | {{Team:Aachen/Header}} | ||
<p class="headline" style="display:none;">Biological Approach</p> | <p class="headline" style="display:none;">Biological Approach</p> | ||
| − | After it became clear that we wanted to enable ''Escherichia coli'' to convert methanol into glycogen we had to find a suitable pathway for methanol assimilation. We found the Methanol Condensation Cycle (MCC) to be the most promising one. For implementing the MCC in ''E. coli'', four additional | + | After it became clear that we wanted to enable ''Escherichia coli'' to convert methanol into glycogen, we had to find a suitable pathway for methanol assimilation. We found the Methanol Condensation Cycle (MCC) to be the most promising one. For implementing the MCC in ''E. coli'', four additional enzymes are required: |
* methanol dehydrogenase 2 from ''Bacillus methanolicus'' (Mdh) | * methanol dehydrogenase 2 from ''Bacillus methanolicus'' (Mdh) | ||
* 3-hexulose-6-phosphate synthase from ''Bacillus methanolicus'' (Hps) | * 3-hexulose-6-phosphate synthase from ''Bacillus methanolicus'' (Hps) | ||
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* phosphoketolase from ''Bifidobacterium adolescentis'' (Xpk) | * phosphoketolase from ''Bifidobacterium adolescentis'' (Xpk) | ||
| − | + | Simultaneously, we developed a strategy for our second module: glycogen accumulation. To enhance glycogen formation, the whole synthesis pathway needs to be upregulated. The three enzymes involved in synthesis are: | |
| − | * GlgC, ADP-glucose pyrophosphorylase | + | * GlgC, the ADP-glucose pyrophosphorylase |
* GlgA, the glycogen synthase | * GlgA, the glycogen synthase | ||
* GlgB, the branching enzyme | * GlgB, the branching enzyme | ||
| − | On top of that accumulation can be considerably increased by knocking out glycogen degradation enzymes. Those are GlgP, the glycogen phosphorylase and GlgX, the debranching enyzme. | + | On top of that, accumulation can be considerably increased by knocking out glycogen degradation enzymes. Those are GlgP, the glycogen phosphorylase and GlgX, the debranching enyzme. |
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| + | By modeling both pathways, we found out that the combination of both modules is possible and can result in remarkable glycogen accumunlation. | ||
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| + | {{Team:Aachen/ReadMore|title=continue|link=/Team:Aachen/InteractiveTour32|picture=Aachen_continue|url=/wiki/images/2/23/Aachen_continue.png}} | ||
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| + | {{Team:Aachen/ReadMore|title=Glycogen|link=/Team:Aachen/Lab/Glycogen|picture=rmGlycogen|url=/wiki/images/4/46/Aachen_tile_Lab_Overview_Glycogen.JPG}} | ||
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| + | {{Team:Aachen/ReadMore|title=Methanol|link=/Team:Aachen/Lab/Methanol|picture=rmMethanol|url=/wiki/images/9/93/Aachen_tile_Lab_Overviwe_Methanol.JPG}} | ||
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| + | {{Team:Aachen/ReadMore|title=Modeling|link=/Team:Aachen/Modeling|picture=rmModeling|url=/wiki/images/5/5d/Aachen_Lab_Overview_Modelling.jpg}} | ||
{{Team:Aachen/Footer|color=green}} | {{Team:Aachen/Footer|color=green}} | ||
Latest revision as of 12:23, 23 November 2015