Team:TU-Eindhoven/LEC/LabTheory

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<h3>Design challenge</h3>
<h3>Design challenge</h3>
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<p>The aim of this project is to design and produce a new multi-color display in which genetically engineered cells function as pixels analogous to how a flat panel display works. In the lab we will make living cells that emit light in response to an electric stimulus. This can be achieved by genetic modification of yeast cells, through the introduction of fluorescent calcium sensors and calcium channels. The plasma membrane of the brewer's yeast <i>Saccharomyces cerevisiae</i> contains the CCH1-MID1 channel that is homologous to mammalian voltage-gated calcium channels (VGCCs). It is hypothesized that upon depolarization of the plasma membrane, calcium ions selectively enter the cytoplasm through these channels <html><aref="#ref_Iida"name="text_Iida"><sup>[1]</sup></a></html>. Light will be emitted through the fluorescence of the GECO protein <html><ahref="#ref_zhao"name="text_zhao"><sup>[2]</sup></a></html>, a calcium sensor that is expressed from a genetically engineered plasmid. When the calcium concentration is high, the GECO protein will fluoresce, but when it is very low, the protein will not fluoresce. Electrical stimulation of the cell will allow calcium to enter into the cytoplasm through the calcium channels and the GECO proteins will start to fluoresce. After a while the calcium concentration will drop to homeostatic levels through active transport of calcium ions by the yeast's vacuole and the fluorescence will cease. Challenges in the laboratory can be found in creating yeast cells with both GECO proteins and a sufficient number of calcium channels incorporated.</p>
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<p>The aim of this project is to design and produce a new multi-color display in which genetically engineered cells function as pixels analogous to how a flat panel display works. In the lab we will make living cells that emit light in response to an electric stimulus. This can be achieved by genetic modification of yeast cells, through the introduction of fluorescent calcium sensors and calcium channels.</p>
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<h3>Design choices</h3>
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<p>The plasma membrane of the brewer's yeast <i>Saccharomyces cerevisiae</i> contains the CCH1-MID1 channel that is homologous to mammalian voltage-gated calcium channels (VGCCs). It is hypothesized that upon depolarization of the plasma membrane, calcium ions selectively enter the cytoplasm through these channels <html><a href="#ref_Iida"name="text_Iida"><sup>[1]</sup></a></html>. Light will be emitted through the fluorescence of the GECO protein <html><a href="#ref_zhao"name="text_zhao"><sup>[2]</sup></a></html>, a calcium sensor that is expressed from a genetically engineered plasmid. When the calcium concentration is high, the GECO protein will fluoresce, but when it is very low, the protein will not fluoresce. Electrical stimulation of the cell will allow calcium to enter into the cytoplasm through the calcium channels and the GECO proteins will start to fluoresce. After a while the calcium concentration will drop to homeostatic levels through active transport of calcium ions by the yeast's vacuole and the fluorescence will cease.</p>
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The important design choices regarding the biological work are motivated below.
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<p>Challenges in the laboratory can be found in creating yeast cells with both GECO proteins and a sufficient number of calcium channels incorporated. The important design choices regarding the biological work are motivated below.</p>
<h4>Chassis</h4>
<h4>Chassis</h4>
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<p>Before this light emitting cell display project could start, it was necessary to decide on a suitable chassis.  Candidates were E. Coli and S. cerevisiae. Both are common model organisms that can be used for protein expression and are cheap to culture. To reach the goal of this project over expression of voltage-gated calcium channel was needed. As soon as it was found that CCH1-MID1, homologous to mammalian voltage-gated calcium channels, could be over expressed in S. cerevisiae, it was decided to use yeast as the chassis in our project.</p>
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<p>Before this light emitting cell display project could start, it was necessary to decide on a suitable chassis.  Candidates were E. Coli and S. cerevisiae. Both are common model organisms that can be used for protein expression and are cheap to culture. To reach the goal of this project over expression of voltage-gated calcium channel was needed. As soon as it was found that CCH1-MID1, homologous to mammalian voltage-gated calcium channels, could be over expressed in S. cerevisiae, it was decided to use yeast as the chassis in our project. In the lab we had a strain called INVSc1 available which was compatiable with the plasmids we were planning to use.</p>
<h4>Plasmids and transformations</h4>
<h4>Plasmids and transformations</h4>

Revision as of 10:30, 26 September 2012