Difference between revisions of "Team:Bordeaux/Yeast results"

 
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<!-- CHOOSING MATERIAL ------------------------------------------------------------------------------------------- -->
 
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        <h3> Yeast Results </h3>
 
              
 
              
        <h5 align="center"><b>CHOICE OF MATERIALS</b></h5>
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<h5 align="center"><b>CHOICE OF MATERIALS</b></h5>
        <br>
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<br>
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<h6 align="justify"><i>FKS1</i> gene</h6  
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<p align=justify>&#10037; <b><i>FKS1</i>gene</b> codes a D-glucan synthase. </p>
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<h6 align="justify"> <i>FKS1</i> gene</h6>
                         
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<p align="justify"> <i>FKS1</i> gene codes a d-glucan synthase. </p>
<h6 align="justify"><i>pYES2</i> plasmid</h6>
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<p align="justify">The plasmid used is the <i>pYES2</i> plasmid provided by <b>M. Didier Thoraval</b> (membrane biogenesis laboratory). It contains an inducible promoter to galactose (<i>GAL1</i>) and a selection gene <i>URA3</i>.</p>
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<h6 align="justify"> Plasmids</h6>
 +
<p align="justify"> &#x2192; A plasmid used was <b>pYES2</b> plasmid provided by <b>M. Didier Thoraval</b> (membrane biogenesis laboratory). It contains an inducible promoter to galactose (<i>GAL1</i>) and a selection gene <i>URA3</i>.</p>
 +
<p align="justify"> &#x2192; A plasmid used was <b>pFA 6a-HIS3MX6-pGAL-3HA</b> plasmid because there is a gene cassette located into  containing <i>GAL1</i> promoter and <i>HIS3</i> selection gene. </p>
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<img style="width:45vw;height:32vw" src="https://static.igem.org/mediawiki/2015/thumb/4/49/Team_Bordeaux_Yeast_plasmid.png/800px-Team_Bordeaux_Yeast_plasmid.png">
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<p class="reference" align ="center"> <b> Figure 1: Plasmids used </p>
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<h6 align="justify"><i>Saccharomyces cerevisiae</i> strain</h6>
 
<h6 align="justify"><i>Saccharomyces cerevisiae</i> strain</h6>
<p align="justify"> All results were obtained with haploid Lnvsc1 strain of Saccharomyces cerevisiae. Its genotype isLeu / Trp / Ura- / Hist- mat α.
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<p align="justify"> All results were obtained with haploid <b>Lnvsc1 strain</b> of Saccharomyces cerevisiae. Its genotype is Leu / Trp / Ura- / Hist- mat α.
 
This genotype allows us an easy selection of transformed cells. </p>
 
This genotype allows us an easy selection of transformed cells. </p>
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<br>
  
                     
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<!-- LABORATORY WORK ------------------------------------------------------------------------------------------- -->
     
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<h5 align="center"><b>LABORATORY WORK</b></h5>                     
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<br>
 +
 
 +
<h6 align="center">1.Overexpression of the gene by plasmidic transformation</h6>     
 +
<p align="justify"> One of the first strategies to overexpress the <i>FKS1</i> gene encoding a D-glucan synthase was to insert it into a plasmid compatible with <i>Saccharomyces cerevisiae</i>. </p>
 +
<p align="justify"> To insert <i>FKS1</i> gene into the chosen plasmid, it was necessary to amplify this gene by PCR on yeast genomic DNA. For that, we designed PCR primers that flank the gene of interest taking into account the issues of specific primers to the target sequences, self-aliasing or primer annealing there between. </p>     
 +
<p align="justify"> We have designed two types of primers that differ in their floating tail. Each of the primer present floating tails with restriction sequences.
 +
<br>&#x2192; A first pair of primer containing sequences recognized by Not1 restriction enzyme on the forward primer and BamH1 restriction enzyme on the reverse primer, which will allow us to integrate the gene in the pYES2 plasmid
 +
<br>&#x2192; A second pair of primer containing sequences recognized by EcoR1 and Xba1 restriction enzyme on the forward primer then, Spe1 and Pst1 on the reverse primer, which will allow us to integrate the gene in pSB1C3 plasmid to constitute a biobrick. </p>
 +
<br>
 +
<p align="justify"> N.B. Unfortunately this strategy could not be completed because PCR amplifications never worked. We tried different process by modeling stringency and with primers hybridizing in the target gene but nothing worked. </p>
 +
<br>
 +
 
 +
<h6 align="center">2.Overexpression of <i>FKS1</i> gene by homologous integration</h6>
 +
<p align="justify"> Thanks to <b>Derek Mc Cluster</b> we tried to overexpress <i>FKS1</i> gene by integrating <i>GAL1</i> inducible promoter upstream of it by the homologous recombination method. </p>
 +
<p align="justify"> To do that, we used a gene cassette located into <b>pFA 6a-HIS3MX6-pGAL-3HA plasmid</b>. This cassette contains <i>GAL1</i> promoter and <i>HIS3</i> selection gene. We amplified the cassette by PCR. </p>
 +
<p align="justify"> The primers used for PCR have floating tails allowing the integration of the cassette upstream <i>FKS1</i> gene. </p>
 +
<p align="justify"> N.B. The amplification product containing the selection gene and the promoter flanked by the homologous recombination of sequences is purified. </p>
 +
<p align="justify"> After transformation and overnight growth, are picked in YNB liquid medium (Gal + His-). </p>
 +
<p align="justify"> We must then determine if the homologous recombination was successful. This verification will be carried out by PCR amplification. We designed a pair of primers specifically hybridizing upstream of the gene of interest and framing the location where construction must integrate. </p>
 +
<p align="justify"> PCR products:
 +
<br>&#x2192; 2kb if homologous recombination worked,
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<br>&#x2192; 1kb if homologous recombination does not take place at the desired location. </p>
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<br>
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<img style="width:40vw;height:30vw" src="https://static.igem.org/mediawiki/2015/e/e0/Bordeaux_chew_back2.png">
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<p class="reference" align ="center"> <b> Figure 2: Gibson Assembly </p>
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<h5 align="center"> <b><i>S. cerevisiae</i> RESULTS </b></h5>
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<p align="justify"> <br> The strategy of overexpressing FKS1 was a failure. Our production results show a dramatical decrease of the Curdlan. It can mean we « broke » the gene during the experiment. Despite these bad results we managed to produce a Biobrick that can be use for every expression in <I>Saccharomyces Cerevisae</I>. </p>
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    <th class="tg-sn50">Successful results</th>
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    <th class="tg-sn50">Unsuccessful results</th>
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    <th class="tg-sn50">Perspectives</th>
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    <td class="tg-s6z2">Cloning in pSB1C3</td>
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    <td class="tg-s6z2">No PCR amplification of FKS1</td>
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    <td class="tg-s6z2">Sulfation of produced Curdlan</td>
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  <tr>
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    <td class="tg-s6z2">Transformation of IVSc1 strain</td>
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    <td class="tg-s6z2">No increase of production in transformed yeast</td>
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    <td class="tg-s6z2">Separation of beta 1,6 and beta 1,3 glucans</td>
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    <td class="tg-s6z2">Curdlan production in wild type</td>
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    <td class="tg-s6z2">Optimization of Curdlan purification</td>
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    <td class="tg-s6z2"></td>
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    <td class="tg-s6z2">Test on plants</td>
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<h6> <a href= "https://2015.igem.org/Team:Bordeaux/Bacteria_results" style=" color: #FF5E00;"> Bacteria Results &#9754;  </a>  Previous Page . Next Page  <a href= "https://2015.igem.org/Team:Bordeaux/Parts" style=" color: #FF5E00;"> &#9755; Our Biobricks </h6>
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Latest revision as of 02:47, 19 September 2015

IGEM Bordeaux 2015





Yeast Results

CHOICE OF MATERIALS

FKS1 gene

FKS1 gene codes a d-glucan synthase.

Plasmids

→ A plasmid used was pYES2 plasmid provided by M. Didier Thoraval (membrane biogenesis laboratory). It contains an inducible promoter to galactose (GAL1) and a selection gene URA3.

→ A plasmid used was pFA 6a-HIS3MX6-pGAL-3HA plasmid because there is a gene cassette located into containing GAL1 promoter and HIS3 selection gene.

Figure 1: Plasmids used

Saccharomyces cerevisiae strain

All results were obtained with haploid Lnvsc1 strain of Saccharomyces cerevisiae. Its genotype is Leu / Trp / Ura- / Hist- mat α. This genotype allows us an easy selection of transformed cells.


LABORATORY WORK

1.Overexpression of the gene by plasmidic transformation

One of the first strategies to overexpress the FKS1 gene encoding a D-glucan synthase was to insert it into a plasmid compatible with Saccharomyces cerevisiae.

To insert FKS1 gene into the chosen plasmid, it was necessary to amplify this gene by PCR on yeast genomic DNA. For that, we designed PCR primers that flank the gene of interest taking into account the issues of specific primers to the target sequences, self-aliasing or primer annealing there between.

We have designed two types of primers that differ in their floating tail. Each of the primer present floating tails with restriction sequences.
→ A first pair of primer containing sequences recognized by Not1 restriction enzyme on the forward primer and BamH1 restriction enzyme on the reverse primer, which will allow us to integrate the gene in the pYES2 plasmid
→ A second pair of primer containing sequences recognized by EcoR1 and Xba1 restriction enzyme on the forward primer then, Spe1 and Pst1 on the reverse primer, which will allow us to integrate the gene in pSB1C3 plasmid to constitute a biobrick.


N.B. Unfortunately this strategy could not be completed because PCR amplifications never worked. We tried different process by modeling stringency and with primers hybridizing in the target gene but nothing worked.


2.Overexpression of FKS1 gene by homologous integration

Thanks to Derek Mc Cluster we tried to overexpress FKS1 gene by integrating GAL1 inducible promoter upstream of it by the homologous recombination method.

To do that, we used a gene cassette located into pFA 6a-HIS3MX6-pGAL-3HA plasmid. This cassette contains GAL1 promoter and HIS3 selection gene. We amplified the cassette by PCR.

The primers used for PCR have floating tails allowing the integration of the cassette upstream FKS1 gene.

N.B. The amplification product containing the selection gene and the promoter flanked by the homologous recombination of sequences is purified.

After transformation and overnight growth, are picked in YNB liquid medium (Gal + His-).

We must then determine if the homologous recombination was successful. This verification will be carried out by PCR amplification. We designed a pair of primers specifically hybridizing upstream of the gene of interest and framing the location where construction must integrate.

PCR products:
→ 2kb if homologous recombination worked,
→ 1kb if homologous recombination does not take place at the desired location.


Figure 2: Gibson Assembly

S. cerevisiae RESULTS


The strategy of overexpressing FKS1 was a failure. Our production results show a dramatical decrease of the Curdlan. It can mean we « broke » the gene during the experiment. Despite these bad results we managed to produce a Biobrick that can be use for every expression in Saccharomyces Cerevisae.



Successful results Unsuccessful results Perspectives
Cloning in pSB1C3 No PCR amplification of FKS1 Sulfation of produced Curdlan
Transformation of IVSc1 strain No increase of production in transformed yeast Separation of beta 1,6 and beta 1,3 glucans
Curdlan production in wild type Optimization of Curdlan purification
Test on plants