Imperial/Wet Lab/Results/ID2.1
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==Materials and Methods== | ==Materials and Methods== | ||
| - | Refer to | + | Refer to [[Imperial/Wet_Lab/Protocols/ID2.1|Protocol]] page. |
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Tested on (Insert link) | Tested on (Insert link) | ||
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'''Raw Data''' | '''Raw Data''' | ||
| - | *[[Media:DNA CONC.xls|Raw Data excel file]] | + | *[[Media:IC 2007 DNA CONC.xls|Raw Data excel file]] |
==Discussion== | ==Discussion== | ||
Revision as of 13:40, 25 October 2007
Testing DNA concentration of pTet-LuxR-pLux-GFPmut3b In vitro
Aims
To determine the optimum concentration of [http://partsregistry.org/Part:BBa_T9002 pTet-LuxR-pLux-GFPmut3b] in vitro.
Materials and Methods
Refer to Protocol page.
Tested on (Insert link)
Results
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Controls:
- Negative Control- Nuclease Free Water was added instead of DNA
Constants:
- Temperature - 25°C
- Total Volume - 60µl
Raw Data
Discussion
Figure 1.1 and Figure 1.2. shows us that the synthesis of GFPmut3b increases with DNA added up until 4µg of DNA. Above this the number of molecules of GFPmut3b produced decreases.
Another interesting observation is that the 6µg of DNA begins producing GFPmut3b greater than 2µg but then levels of before 2µg. This is thought to be because the data displayed on the figures are averages of 2 samples, one of the samples levels off sooner than the other and so brings the average down. However, the results do tell us that 6µg is lower than the 4µg, therefore the 4µg is the optimum DNA for our in vitro chassis.
This agrees with promegas guide on using the commcerial cell extract in vitro chassis. The guide states that 4µg is the maximum and above this there is problems with premature termination of translational products
Conclusion
To conclude the following approximations can be made:
- Optimum DNA concentrations - 4µg of DNA
