Difference between revisions of "Team:Potsdam/Design"
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IAA concentrations were measured with GC-MS and compared to levels corresponding to free diffusion of the enzymes. | IAA concentrations were measured with GC-MS and compared to levels corresponding to free diffusion of the enzymes. | ||
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| + | <h1>dCas9 approach:</h1> | ||
| + | Scaffolds for inducing metabolic channelling with nucleic acids has been tried in several different ways already. For example, by the iGEM ZJU China team of 2012, where RNA cloverleaf structures were used to bind IAA enzymes to RNA.1 They fused the enzymes to RNA-binding proteins from viral coat proteins (MS2 and PP7). These bound to the RNA and thus put the IAA enzymes close to each other (see picture below). With this concept, they were able to record a 1.4-fold increase in IAA output. | ||
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| + | <dl class="bildunterschrift"> | ||
| + | <dt><img src="https://static.igem.org/mediawiki/2017/1/1b/China_Skizze.png" alt="Bildbeschreibung" title="Bildbeschreibung" width="90%" align="center"></dt> | ||
| + | <dd align="center">Project design of ZJU China 2012</dd> | ||
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Revision as of 14:16, 1 November 2017
The number of biotechnological applications has skyrocketed and have evolved to be one of the most ubiquitous aspects in our daily life in the past years. From uses in food industry to dietary supplements and science, white biotechnology is everywhere.
That’s why we try to recreate a widespread natural phenomenon called metabolic channelling synthetically to increase the yield biochemical reactions. Metabolic channelling occurs when the enzymes responsible for a specific reaction are in close proximity to each other, and thereby decrease the diffusion time of the substrates (see animation below).
*Animation zur Verdeutlichung von metabolic channelling*
In our first method, we utilize the DNA-binding function of deadCas9 (dCas9) to bind two enzymes of the Indoleacetic acid (IAA) pathway, IAA tryptophan monooxygenase (IAAM) and indoleacetamide hydrolase (IaaH) on a DNA-scaffold which we introduce into E.coli. By binding the enzymes on DNA, we decrease the distance the substrates have to travel in the cytoplasm and hope to achieve a higher output of Indoleacetic acid.
The second method revolves around Liquid-liquid-phase separation, a process naturally occurring in cells[1]. Through this process, proteins aggregate together to form droplets or membrane-less bodies in the cytoplasm or nucleoplasm. This can be thought of as lipid droplets forming in water, just with proteins. Examples for this process in nature are stress granules or cajal bodies. The formation of droplets has already been studied by attaching YFP to Ddx4 (Nott et al.)[2], a protein known for aggregation. There are also indicators for this to happen in bacteria3. To use this mechanism for improvement of enzyme efficiency, the YFP-coding region will be replaced by the coding region of the IAA enzymes and expressed in yeast, because of droplet size.
*Video mit der Bildung von droplets in HeLa zellen*
Formation of fluorescing droplets in HeLa cells, courtesy of Tim Nott
IAA concentrations were measured with GC-MS and compared to levels corresponding to free diffusion of the enzymes.
dCas9 approach:
Scaffolds for inducing metabolic channelling with nucleic acids has been tried in several different ways already. For example, by the iGEM ZJU China team of 2012, where RNA cloverleaf structures were used to bind IAA enzymes to RNA.1 They fused the enzymes to RNA-binding proteins from viral coat proteins (MS2 and PP7). These bound to the RNA and thus put the IAA enzymes close to each other (see picture below). With this concept, they were able to record a 1.4-fold increase in IAA output.
- Project design of ZJU China 2012
Main sponsors:
