Team:TU-Eindhoven/Future applications/Developments

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Furthermore, the influence of <span class="pink">calcium diffusion</span> through the cell could be taken into account in an extended model. Instead of MATLAB, <span class="pink">COMSOL</span> simulation software can be used, because it is less complex to model dependency on both space and time in COMSOL. Subsequently, the results of the model will be compared to the results of the experiments.  
Furthermore, the influence of <span class="pink">calcium diffusion</span> through the cell could be taken into account in an extended model. Instead of MATLAB, <span class="pink">COMSOL</span> simulation software can be used, because it is less complex to model dependency on both space and time in COMSOL. Subsequently, the results of the model will be compared to the results of the experiments.  
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<h3>Lab</h3>
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<p>The more research that is conducted with yeast, the more informed and controlled future research can be. Yeast is incredibly flexible, it is safe and yeast also shares many genes with human cells. So if you want to find out what a particular drug does to a certain human gene, you can often test it on yeast cells first.</p>
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<p>A good way to characterize the whole yeast cell is still missing. This would be useful to validate the computational models and to ‘debug’ the yeast. However, this is a lot of work, because every part of the characterization is already a project in itself.
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For instance:</p>
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<li>The localization of the channels and the control of that. This can be done with fluorescence microscopy, because there are fusion proteins available from CCH1 and Mid1 with EGFP<html><a href="#ref_Iida"name="text_Iida"><sup>[1]</sup></a></html>. It is also possible to influence the localization within the cell, this is currently a major area of research in cellular biology.</li>
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<li>The measurement of the dynamic response of the yeast on the calcium influx. This can be done with fluorescence-lifetime imaging microscopy, to measure calcium concentrations in living cells at multiple scales using lifetime contrast. However, only if you are in possession of such an expensive device and if you are able to work with it.</li>
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<li>Optimization of protocols for the cultivation of the yeast, with an optimal calcium regulation. These protocols can be used for measuring the expression of calcium channels and measure the set-point concentration of calcium in the periplasm, ER, Golgi, and vacuole medium.</li>
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<li>Over expression of calcium pumps in yeast. There is still uncertainty about the export mechanism of calcium in yeast cells. To make sure that the calcium does not accumulate in the cell, to get a good response time, over expression of calcium pumps is desirable.</li></ul>
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<p>It was also very time consuming to transform three insert, one by one, in yeast. A better approach would be to put all inserts in one shuttle vector of E.coli, with different promoters to regulate their expression. This would decrease the waiting time because the growth rate of yeast cells is not more than 1/3 of the growth rate of E.coli.</p>
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<p>Beside those future developments there is always more room for improvements and developments.</p>
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<h3>References</h3>
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<li><a href="#text_Iida" name="ref_Iida">[1]</a>  K. Iida, et al., Essential, completely conserved glycine residue in the domain III S2S3 linker of voltage-gated calcium channel α1 subunits in yeast and mammals, Journal of Biological Chemistry 282: 25659-25667, (2007)</a></li>
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Revision as of 00:29, 27 September 2012