Difference between revisions of "Part:BBa K3570006"
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<li>Add 400uL of LiAc/TE, mix thoroughly by inverting the tube 10 times.<br> | <li>Add 400uL of LiAc/TE, mix thoroughly by inverting the tube 10 times.<br> | ||
Yeast competent cells should be used on the same day that they have been prepared.</li> | Yeast competent cells should be used on the same day that they have been prepared.</li> | ||
− | <strong>2. Yeast transformation</strong></p> | + | |
+ | <p><strong>2. Yeast transformation</strong></p> | ||
<p><strong>-Materials</strong></p> | <p><strong>-Materials</strong></p> | ||
<p>Transforming DNA | <p>Transforming DNA |
Revision as of 20:43, 25 October 2020
DPP1 upstream homologous sequence
Usage
DPP1 upstream homology arm part shall be used together with DPP1 downstream homology arm part (BBa_K3570007) to target a functional yeast integration locus. When DPP1 up put to 5' of the biobrick together with DPP1 downstream to the 3', the biobrick can be integrated into the S. cerevisiae's genome. It will do homologous recombination within the Diacylglycerol pyrophosphate phosphatase 1 (DPP1) gene.
This sequence was identified from a personal communication with Dr. Gilles Truan.
Experiments
We used this part in the insertion of the tHMG1 and CrtE genes (part BBa_K3570000) in the yeast genome. Below is our yeast transformation protocol and our results which show that we have successfully integrated this part and that the BBa_K3570006 and BBa_K3570007 parts work.
A. Protocols
1. Preparation of yeast competent cells
- Materials
75 mL of YPD medium.
50mL falcon-tube.
Centrifuge
26mL of LiAc/TE.
- Methods
Yeast competent cells should be used on the same day that they have been prepared.
2. Yeast transformation
-Materials
Transforming DNA Competent yeast cells 10mg/ml carrier DNA (SS-DNA) 50% PEG in 100mM LiAc/TE NaCl YNB plates (with all the amino acids except histidine) 30ºC warm bath 42ºC warm bath 30ºC incubator table-top microcentrifuge 1.5mL microcentrifuge tube
-Method
Positive control was performed by adding 1uL of pR313 instead of the transforming DNA, and negative control had no DNA.
- Vortex solution.
- Incubate 45min at 30ºC.
- Add 13uL of DMS0 and vortex solution.
- Incubate 15min at 42ºC.
- Add 450uL of NaCl and vortex solution.
- Centrifuge at 10000rpm for 1min.
- Remove flowthru and resuspend pellet with 80uL of NaCl.
- Plate solution on YNB plates (with all the amino acids except for the ….)
- Incubate at 30ºC for two to three days.
- S. cerevisiae genome, chromosome IV, DPP1 gene. GenBank: CP046084.1
- 10INCOMPATIBLE WITH RFC[10]Illegal PstI site found at 50
- 12INCOMPATIBLE WITH RFC[12]Illegal PstI site found at 50
- 21COMPATIBLE WITH RFC[21]
- 23INCOMPATIBLE WITH RFC[23]Illegal PstI site found at 50
- 25INCOMPATIBLE WITH RFC[25]Illegal PstI site found at 50
- 1000COMPATIBLE WITH RFC[1000]
B. Results and discussion:
Since the construction of the part BBa_K3570000 was successful, we proceeded to the next step: integration in the yeast genome. The plasmid was digested with enzymes SbfI and EcoRI and purified to transform the yeast Saccharomyces cerevisiae. The yeast was then grown on YNB HIS- for 3 days. At the third try, we were able to observe around 20 colonies in our yeast transformation, about the same on the positive control and none on the negative control plate.
To verify our colonies we performed a genomic PCR using the TaKaRa PCR Amplification Kit, so we randomly chose eight clones from our transformation and one from the positive control plate (Figure 7).
All clones have the expected size (1.2kb), and the control where we inserted pRS313 does not show any band. We have successfully integrated tHmg1 and CrtE into the yeast using DPP1 homology sequence!
References
Sequence and Features