Team:Alberta/Project/ModelValid

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<p>In order to achieve a series of double deletions and accurately predict the model’s effects in vivo, MATLAB was used to produce a program which could identify genes which worked in combination.  The <a href="https://2009.igem.org/Team:Alberta/Modeling/DualDeletionTest"> DualDeletionTest.m</a> file is designed to slowly delete reactions one at a time to determine which reactions are essential to the cell.  The data which was saved, was the genes (listed by blattner number) which catalyze the reaction.  The list was cross referenced with the PEC database to ensure that all genes were considered unessential.  Once completed, the list was narrowed down to reactions which used only two genes.  Finally, the two genes were deleted in the model and their resulting growth rate was recorded.  This was done to clarify that the growth rate was either zero or incredibly low (as predicted by the model).  Following this, two sets of genes were selected to perform wetlab experiments with.  These were CysM and CysK, as well as MetH and MetD.  (To see data produced by DualDeletionTest.m and the processed data click <a href="https://2009.igem.org/Image:UofA_DualDeletionData.xls"> here</a>).
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<p>In order to achieve a series of double deletions and accurately predict the model’s effects in vivo, MATLAB was used to produce a program which could identify genes which worked in combination.  The <a href="https://2009.igem.org/Team:Alberta/Modeling/DualDeletionTest"> DualDeletionTest.m</a> file is designed to slowly delete reactions one at a time to determine which reactions are essential to the cell.  The data which was saved, was the genes (listed by blattner number) which catalyze the reaction.  The list was cross referenced with the PEC database to ensure that all genes were considered unessential.  Once completed, the list was narrowed down to reactions which used only two genes.  Finally, the two genes were deleted in the model and their resulting growth rate was recorded.  This was done to clarify that the growth rate was either zero or incredibly low (as predicted by the model).  Following this, two sets of genes were selected to perform wetlab experiments with.  These were CysM and CysK, as well as MetH and MetD.  (To see data produced by DualDeletionTest.m and the processed data click <a href="https://2009.igem.org/Image:UofA_DualDeletionData.xls"> here</a>).</p>
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<p>In order to delete one of the genes of interest, cells from the Keio Knockout Collection were procured which contained knockouts of CysK and MetH.  These cell lines replaced each gene with a Kanamycin resistance cassette flanked by two FRT sites allowing for its removal with FLP recombinase.  In order to remove the second gene, an ampicillin resistance cassette was produced via PCR with 50 bp of homology on either side which corresponds to the sequences on either side of the second gene to be knocked out. (Click <a href="https://2009.igem.org/Image:UofA_Matlab_Primers.xls"> here</a to see the PCR primers).</P>
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<P>pKD46 carries the lambda recombinase genes which allow for the ampicillan homology cassette to recombine into the genomes.  Lambda recombinase is a temperature sensative plasmid and its activity is induced by arabinose.  However, since the cell should be no longer viable after insertion of the cassette, a control plasmid should be used to ensure that the dual gene deletion is causing death.  The Keio Knockout Collection uses the BW25113 E.coli strain.  This was used as our control cell strain.  In theory, insertion of the cassette should not cause death in the control strain since there will only be one deletion made.  This will ensure that the cassette is being inserted correctly and it is the cause of the Keio Collection cell line's death. 
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<h4>Control Plasmid Experiment</h4>
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<img src="https://static.igem.org/mediawiki/2009/b/b0/UofA_MATLAB_Control.JPG">
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<h4>Keio Knockout Plasmid Experiment</h4>
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<img src="https://static.igem.org/mediawiki/2009/3/3b/UofA_MATLAB_Delete.JPG">
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Revision as of 22:18, 17 October 2009

University of Alberta - BioBytes










































































































Model Validation

The majority of essential gene experiments in the literature involve single gene knock outs. However, our model has a unique ability to predict what combinations of gene deletions will be lethal. However it is important to determine how accurate the model is in determining these multiple gene deletion results. For this reason, the Model Validation attempts to answer the question; is a series of dual deletions which cause death in our model accurately reflected in vivo?

Unfortunately, we are still in the process of completing this component of the project and hope to have it completed prior to the date of the competition. Please see our poster at the competition for additional information on the validation experiments.

The Experiment

In order to achieve a series of double deletions and accurately predict the model’s effects in vivo, MATLAB was used to produce a program which could identify genes which worked in combination. The DualDeletionTest.m file is designed to slowly delete reactions one at a time to determine which reactions are essential to the cell. The data which was saved, was the genes (listed by blattner number) which catalyze the reaction. The list was cross referenced with the PEC database to ensure that all genes were considered unessential. Once completed, the list was narrowed down to reactions which used only two genes. Finally, the two genes were deleted in the model and their resulting growth rate was recorded. This was done to clarify that the growth rate was either zero or incredibly low (as predicted by the model). Following this, two sets of genes were selected to perform wetlab experiments with. These were CysM and CysK, as well as MetH and MetD. (To see data produced by DualDeletionTest.m and the processed data click here).

In order to delete one of the genes of interest, cells from the Keio Knockout Collection were procured which contained knockouts of CysK and MetH. These cell lines replaced each gene with a Kanamycin resistance cassette flanked by two FRT sites allowing for its removal with FLP recombinase. In order to remove the second gene, an ampicillin resistance cassette was produced via PCR with 50 bp of homology on either side which corresponds to the sequences on either side of the second gene to be knocked out. (Click here

pKD46 carries the lambda recombinase genes which allow for the ampicillan homology cassette to recombine into the genomes. Lambda recombinase is a temperature sensative plasmid and its activity is induced by arabinose. However, since the cell should be no longer viable after insertion of the cassette, a control plasmid should be used to ensure that the dual gene deletion is causing death. The Keio Knockout Collection uses the BW25113 E.coli strain. This was used as our control cell strain. In theory, insertion of the cassette should not cause death in the control strain since there will only be one deletion made. This will ensure that the cassette is being inserted correctly and it is the cause of the Keio Collection cell line's death.

Control Plasmid Experiment

Keio Knockout Plasmid Experiment