Team:Johns Hopkins/Vit/Results

From 2011.igem.org

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On a first visual comparison of growth on dough media vs YPD we did see a significantly slower growth on dough media than on YPD. This is to be expected considering there is a large excess of nutrients on the YPD plates. There was still significant growth on the dough media plates however, enough to show that it would be viable to use in bread.
On a first visual comparison of growth on dough media vs YPD we did see a significantly slower growth on dough media than on YPD. This is to be expected considering there is a large excess of nutrients on the YPD plates. There was still significant growth on the dough media plates however, enough to show that it would be viable to use in bread.
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=HPLC=
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=Spectroscopy and HPLC=
Based on the results of our Spectroscopy experiments measuring beta-carotene versus time and characterization by the use of HPLC, we can see that the production of beta-carotene over time increases at a (rate).  The results of the HPLC confirm that the yeast cells are in fact producing beta carotene, as the absorption peak at 450nm corresponds to the absorption maxima of beta-carotene.  Before running the samples on the HPLC, beta carotene was extracted from cell extract using hexane, as it would only isolate highly hydrophobic molecules, such as beta-carotene. As seen in following Spectroscopy and HPLC graphs, beta carotene production and characterization can be quantified.     
Based on the results of our Spectroscopy experiments measuring beta-carotene versus time and characterization by the use of HPLC, we can see that the production of beta-carotene over time increases at a (rate).  The results of the HPLC confirm that the yeast cells are in fact producing beta carotene, as the absorption peak at 450nm corresponds to the absorption maxima of beta-carotene.  Before running the samples on the HPLC, beta carotene was extracted from cell extract using hexane, as it would only isolate highly hydrophobic molecules, such as beta-carotene. As seen in following Spectroscopy and HPLC graphs, beta carotene production and characterization can be quantified.     

Revision as of 02:39, 25 September 2011

VitaYeast - Johns Hopkins University, iGEM 2011

Results

The strains transformed with the caretenogenic genes are a bright orange color due to all the beta-carotene they produce, as beta-carotene is an orange pigment. We confirmed its presence via HPLC using a standard.

On a first visual comparison of growth on dough media vs YPD we did see a significantly slower growth on dough media than on YPD. This is to be expected considering there is a large excess of nutrients on the YPD plates. There was still significant growth on the dough media plates however, enough to show that it would be viable to use in bread.

Spectroscopy and HPLC

Based on the results of our Spectroscopy experiments measuring beta-carotene versus time and characterization by the use of HPLC, we can see that the production of beta-carotene over time increases at a (rate). The results of the HPLC confirm that the yeast cells are in fact producing beta carotene, as the absorption peak at 450nm corresponds to the absorption maxima of beta-carotene. Before running the samples on the HPLC, beta carotene was extracted from cell extract using hexane, as it would only isolate highly hydrophobic molecules, such as beta-carotene. As seen in following Spectroscopy and HPLC graphs, beta carotene production and characterization can be quantified.


Beta carotene extracted from yeast strain 210


1st round PCR Gel (put in notebook section)


2nd round PCR Gel (leave here)
Strain 39 YB-mCherry RFP tagged expression (leave here)
Strain 39 Control (put in notebook section)
Strain 39 beta carotene production (leave here)
Strain 39 beta carotene production Control (put in notebook section)