Team:Valencia Biocampus/Yeast

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<h2>Yeast Subteam</h2>
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Revision as of 10:28, 30 August 2012



Yeast Subteam


THE IDEA




Our aim in this part of the project is to detect when the yeast starts to ferment. To do this, we are going to use two gene constructions. The first construction consists of the ADH2 promoter fused to the YAP1 protein coding sequence. In the second construction the TRR promoter is fused to the GFP (Green Fluorescence Protein) coding sequence.

We use the ADH2 promoter (alcohol dehydrogenase) to sense the glucose/ethanol concentration. When this promoter is activated, YAP1 is expressed. This protein will attach to TRR promoter (thioredoxin reductase), which will become activated if the constitutive yeast protein SKN7 is in its oxidized form and also interacts with the promoter. This activation will enable transcription of GFP. H2O2 has to be added in order to oxidize the SKN7 protein.

Outline

- We ordered the DNA constructions: ADH2 promoter-YAP1 protein and TRR promoter-GFP protein.

- We had the Yeplac181 and Yep352 yeast vectors in our laboratory.

- We carried out four transformations of E. coli, one for each DNA (the two constructions and the two vectors), in order to amplify them. See the Transformation Protocol Using Heat Shock.

- Once amplified, we extracted the DNA. See the Mini-prep Protocol.

- We ligated the TRR-GFP construction with the Yep352 vector and the ADH2-YAP1 construction with the Yeplac181 vector.

- We introduced the products of the ligations in yeast. See the Yeast Transformation Protocol.

- We measured the fluorescence obtained for different glucose concentrations.

- We obtained a curve relating these values.