Team:UIUC Illinois/Project/Results

From 2013.igem.org

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Breakdown <br> <br>
Breakdown <br> <br>
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As you may recall CDH ( ) is responsible for the breakdown of L-carnitine down our alternative pathway. We tested the function and production of CDH using a Spectrophotometric NADH pathway. As shown in the following reaction ( PUT REACTION PICTURE BELOW) NADH is a product of when this enzyme converts L-carnitine into 3-dehydrocarnitine. Thus we can conclude if our enzyme is working based on the levels of NADH accumulation after adding L-carnitine to a media containing our CDH enzyme. <br>
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As you may recall CDH ( ) is responsible for the breakdown of L-carnitine down our alternative pathway. We tested the function and production of CDH using a Spectrophotometric NADH pathway. As shown in the following reaction ( PUT REACTION PICTURE BELOW) NADH is a product of when this enzyme converts L-carnitine into 3-dehydrocarnitine. Thus we can conclude if our enzyme is working based on the levels of NADH accumulation after adding L-carnitine to a media containing our CDH enzyme.
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<a href="https://2013.igem.org/File:UIUCL-carntine_degredation.PNG"></a>
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<img src="https://2013.igem.org/File:UIUCL-carntine_degredation.PNG" width="720" height="294" alt="degradation" />
This was done by retrieving the cytoplasmic extract of our cells after induction of our CDH plasmid. This extract now containing the enzyme was tested to see NADH accumulation after adding L-carnitine. A spectrophotometer is able to give you this reading because NADH has specific absorbance wavelength that can be measured.  
This was done by retrieving the cytoplasmic extract of our cells after induction of our CDH plasmid. This extract now containing the enzyme was tested to see NADH accumulation after adding L-carnitine. A spectrophotometer is able to give you this reading because NADH has specific absorbance wavelength that can be measured.  
By comparing the next two graphs you can see that in comparison to the background accumulation of NADH that our cytoplasmic extract from the cell containing our genes accumulation of NADH is a lot higher. This indicates that our genes have created the correct enzyme since once l-carnitine is added the NADH accumulation increases indicating that our intended reaction is proceeding. <br>
By comparing the next two graphs you can see that in comparison to the background accumulation of NADH that our cytoplasmic extract from the cell containing our genes accumulation of NADH is a lot higher. This indicates that our genes have created the correct enzyme since once l-carnitine is added the NADH accumulation increases indicating that our intended reaction is proceeding. <br>

Revision as of 01:04, 28 September 2013

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Breakdown

As you may recall CDH ( ) is responsible for the breakdown of L-carnitine down our alternative pathway. We tested the function and production of CDH using a Spectrophotometric NADH pathway. As shown in the following reaction ( PUT REACTION PICTURE BELOW) NADH is a product of when this enzyme converts L-carnitine into 3-dehydrocarnitine. Thus we can conclude if our enzyme is working based on the levels of NADH accumulation after adding L-carnitine to a media containing our CDH enzyme. degradation This was done by retrieving the cytoplasmic extract of our cells after induction of our CDH plasmid. This extract now containing the enzyme was tested to see NADH accumulation after adding L-carnitine. A spectrophotometer is able to give you this reading because NADH has specific absorbance wavelength that can be measured. By comparing the next two graphs you can see that in comparison to the background accumulation of NADH that our cytoplasmic extract from the cell containing our genes accumulation of NADH is a lot higher. This indicates that our genes have created the correct enzyme since once l-carnitine is added the NADH accumulation increases indicating that our intended reaction is proceeding.
Furthermore we are required to test the levels of NADH production naturally in the cytoplasmic extract without the effects of L-carnitine. As depicted below both cytoplasmic extract from the backbone alone and the one with our genes did not result in an increase of NADH over the time span. This indicates that when L-carnitine was added to the cytoplasmic extract of the bacteria containing our gene the NADH concentration increased thus proving our desired enzyme is being produced and functioning as predicted.

Uptake

As you may recall the uptake system depends on two genes. CbcVW is a memebrane complex that allows L-carnitine to be shuttled through the membrane. CaiX is a free floating protein and directs the L-carnitine to our membrane protein thus helping the uptake of l-carnitine. We desired to measure the uptake of L-carnitine with Liquid Chromatography Mass Spectrometer. We will use this device by measuring the concentration of L-carnitine in the supernatant initially and finally. We prepared sample of Nissle with our genes and just with our backbone. Then we took samples of the supernatant initially and finally. By comparing L-carnitine concentrations before and after the amount of L-carnitine that was uptaken will be visible.
By looking at the graphs below you can see that our concentration of L-carnitine finally is drastically lower than the concentration of L-carnitine initially. It can also be seen that the bear backbone does not affect the concentration of l-carntine because initially and finally the concentration of l-carnitine is virtually identical. Conclusively it can be seen by this final overlaid graph of L-carnitine with our gene insert, that the concentration of L-carnitine in the supernatant drastically decreases over time. This indicates that our transporter are indeed accelerating the amount of L-carnitine that is it uptakes.