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Team:TU-Delft/part3
From 2012.igem.org
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Yeast strain BY4741; Mat a; his3D1; leu2D0; met15D0; ura3D0; YJL157c::kanMX4 is transformed with the GPA1 ko PCR product, according to the yeast transformation protocol. 100 ng of DNA is used for transformation. After 3 days 3 colonies could be seen on the plate. There where zero colonies on the control plate. | Yeast strain BY4741; Mat a; his3D1; leu2D0; met15D0; ura3D0; YJL157c::kanMX4 is transformed with the GPA1 ko PCR product, according to the yeast transformation protocol. 100 ng of DNA is used for transformation. After 3 days 3 colonies could be seen on the plate. There where zero colonies on the control plate. | ||
| - | <br/>To check whether the knock-out reaction | + | <br/>To check whether the knock-out reaction is successful primers A and D bind to 5’ upstream and 3’ downstream regions of the GPA1 gene, the B and C primers anneal in the URA gene which is knocked in. <br> |
| - | Cultures of colony 2 and wildtype yeast where grown in YPG (YP+2% glucose) overnight for chromosomal extraction using the MO BIO chromosomal extraction kit ( | + | Cultures of colony 2 and wildtype yeast where grown in YPG (YP+2% glucose) overnight for chromosomal extraction using the MO BIO chromosomal extraction kit (<a href="http://www.mobio.com/images/custom/file/protocol/15800.pdf">protocol</a>). A PCR reaction was performed on extracted genomic DNA of the grown strains, using an annealing gradient of 45, 55 and 65 C and 15 ng or 30 ng template DNA. Reactions AD, AB and CD where performed according to the conditions summarized in table 11. PCR product is put on gel and shown in figure 5. Here can be seen that colony 2 (B) shows both expected band length in the AB and CD reactions, but no bands in the AD reaction. Colony 1 (A) shows only bands in the AD reaction, so the knock-out was unsuccessful. Colony 3 (C) shows inconsistent bands in reactions AD (lane 5 and 7), BC (lane 10) and CD (lane 14 and 15), also not of the expected length.</p> |
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<h6>Table 11 Taq PCR conditions for KO check.</h6> | <h6>Table 11 Taq PCR conditions for KO check.</h6> | ||
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<h6>Figure 5: 1% agarose gel in TAE, 40 min run on 100 V. PCR products of Genomic extracted DNA. Colony 1 (A), Colony 2 (B), and Colony 3 (C) are shown. In the picture can be seen: 1 DNA Smarladder, 2 AD reaction with 15 ng template and 45 C, 3 AD reaction with 15 ng template and 55 C, 4 AD reaction with 15 ng template and 65 C, 5 AD reaction with 30 ng template and 45 C, 6 AD reaction with 30 ng template and 55 C, 7 AD reaction with 30 ng template and 65 C, 8 AB reaction with 15 ng template and 45 C, 9 AB reaction with 15 ng template and 55 C, 10 AB reaction with 15 ng template and 65 C, 11 AB reaction with 30 ng template and 45 C, 12 AB reaction with 30 ng template and 55 C, 13 AB reaction with 30 ng template and 65 C, 14 CD reaction with 15 ng template and 45 C, 15 CD reaction with 15 ng template and 55 C, 16 CD reaction with 15 ng template and 65 C, 17 CD reaction with 30 ng template and 45 C, 18 CD reaction with 30 ng template and 55 C, 19 CD reaction with 30 ng template and 65 C, 20 smartladder.</h6> | <h6>Figure 5: 1% agarose gel in TAE, 40 min run on 100 V. PCR products of Genomic extracted DNA. Colony 1 (A), Colony 2 (B), and Colony 3 (C) are shown. In the picture can be seen: 1 DNA Smarladder, 2 AD reaction with 15 ng template and 45 C, 3 AD reaction with 15 ng template and 55 C, 4 AD reaction with 15 ng template and 65 C, 5 AD reaction with 30 ng template and 45 C, 6 AD reaction with 30 ng template and 55 C, 7 AD reaction with 30 ng template and 65 C, 8 AB reaction with 15 ng template and 45 C, 9 AB reaction with 15 ng template and 55 C, 10 AB reaction with 15 ng template and 65 C, 11 AB reaction with 30 ng template and 45 C, 12 AB reaction with 30 ng template and 55 C, 13 AB reaction with 30 ng template and 65 C, 14 CD reaction with 15 ng template and 45 C, 15 CD reaction with 15 ng template and 55 C, 16 CD reaction with 15 ng template and 65 C, 17 CD reaction with 30 ng template and 45 C, 18 CD reaction with 30 ng template and 55 C, 19 CD reaction with 30 ng template and 65 C, 20 smartladder.</h6> | ||
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| - | <p>We concluded that in colony 2 GPA1 has successfully been knocked out. The following test is to transform Fus1-GFP into this ?far1 ?gpa1 yeast and to see difference in fluorescence output when compared to ?far1 yeast strain when induced by pheromone alpha. Expected is that due to lack of alpha subunit of the pheromone receptor, no or less light signal is detected. | + | <p>We concluded that in colony 2 GPA1 has successfully been knocked out. The following test is to transform Fus1-GFP into this ?far1 ?gpa1 yeast and to see difference in fluorescence output when compared to ?far1 yeast strain when induced by pheromone alpha. Expected is that due to lack of alpha subunit of the pheromone receptor, no or less light signal is detected. A full description of the process can be seen <a href="2012.igem.org/wiki/Team:TU-Delft/results>here</a>. |
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Revision as of 00:23, 27 September 2012
Introduction
By combining the olfactory receptor and the FUS1pr-EGFP reporter, a complete yeast olfactory system is obtained. If the corresponding ligand binds to the receptor the FAR1 promoter is turned on and the EGFP is expressed. This EGFP signal can be read out by a fluorescence meter. If the olfactory system will be implemented as a diagnostics tool in developing countries, the EGFP reporter should be changed by a visible reporter.
Besides the induction of the FUS1 promoter the cells also go in growth arrest mediated by the FAR1 promoter. However it is undesirable that the cells stop growing once they respond to a ligand. Therefore it is needed to knock out the FAR1 promoter.
Parts
The receptor constructs and the reporter constructs are combined to have one complete olfactory system. The following biobricks are created:
BBa_K775005
BBa_K775006
BBa_K775007
BBa_K775008
Results
Knock out FAR1
Setup
YeastOutcome
or making a functional knockout, yeast strains BY4741; Mat a; his3D1; leu2D0; met15D0; ura3D0; YJL157c::kanMX4 and BY4741; Mat a; his3D1; leu2D0; met15D0; ura3D0; YHR005c::kanMX4 were used (Euroscarf). Also knockout cassette pUG72 is used (Euroscarf). The LoxP-Ura-LoxP is elongated using the pFx polymerase protocol. The PCR program and primer sequences in table 1 yielded a product which is put on a gel shown in figure 1. Here a band can be recognized between 2000 and 1500 nucleotides, which corresponds to the 1669 nucleotide PCR product.Table 1 PCR program for elongation of knockout cassette for knocking out Far1 and Gpa1 and primers used for elongation.
| Repeats | Temperature | Duration | 5x | 95 | Melting | 2:00 |
|---|---|---|---|
| 51 | Annealing | 1:00 | |
| 68 | Elongation | 2:00 | |
| 25x | 95 | Melting | 2:00 |
| 61 | Annealing | 1:00 | |
| 68 | Elongation | 2:00 |
| GPA ko fw TTAGCATCACATCAATAATCCAGAGGTGTATAAATTGATATATTAAGGTAGGAAATAATGCAGCTGAAGCTTCGTACGC |
| GPA ko rv TGCATCTTCGGAAACAGAATTTACGTATCTAAACACTACTTTAATTATACAGTTCCTTCAGCATAGGCCACTAGTGGATCTG |
| FAR1 ko fw ACACAAAGTCTATAGATCCACTGGAAAGCTTCGTGGGCGTAAGAAGGCAATCTATTAATGCAGCTGAAGCTTCGTACGC |
| FAR1 ko rv GAAAAAAAAAAAAGGAAAAGCAAAAGCCTCGAAATACGGGCCTCGATTCCCGAACTACTAGCATAGGCCACTAGTGGATCTG |
| GPA ko fw short TAATCCAGAGGTGTATAAATTGATATATTAAGGTAGGAAATAATGCAGCTGAAGCTTCGTACGC |
| GPA ko rv short AGAATTTACGTATCTAAACACTACTTTAATTATACAGTTCCTTCAGCATAGGCCACTAGTGGATCTG |
| FAR1 ko fw short ATCCACTGGAAAGCTTCGTGGGCGTAAGAAGGCAATCTATTAATGCAGCTGAAGCTTCGTACGC |
| FAR1 ko rv short AAAAGCAAAAGCCTCGAAATACGGGCCTCGATTCCCGAACTACTAGCATAGGCCACTAGTGGATCTG |
| ATF1 ko fw gaaaataaaaaacggCACTTCATCAGTATCACAAATACCATCAATTTATCAGCTCTCATGCAGCTGAAGCTTCGTACGC |
| ATF1 ko rv ggttatttacacgacatAATCATATTGTCGAATAATATCAGTCAAGCATCATGTGAGATCTAGCATAGGCCACTAGTGGATCTG |
| ATF1 ko fw short CACTTCATCAGTATCACAAATACCATCAATTTATCAGCTCTCATGCAGCTGAAGCTTCGTACGC |
| ATF1 ko rv short AATCATATTGTCGAATAATATCAGTCAAGCATCATGTGAGATCTAGCATAGGCCACTAGTGGATCTG |
Figure 1: 1% agarose in TAE ~45 run on 80 Volts. In the picture can be seen: 1 SmartLadder, 2 Far1 short PCR product, 3 Far1 long PCR product, 4 Gpa1 short PCR product, 5 Gpa1 long PCR product, 6 Atf1 short PCR product, 7 Atf1 long PCR product.
Yeast strain BY4741; Mat a; his3D1; leu2D0; met15D0; ura3D0; YJL157c::kanMX4 is transformed with the GPA1 ko PCR product, according to the yeast transformation protocol. 100 ng of DNA is used for transformation. After 3 days 3 colonies could be seen on the plate. There where zero colonies on the control plate.
To check whether the knock-out reaction is successful primers A and D bind to 5’ upstream and 3’ downstream regions of the GPA1 gene, the B and C primers anneal in the URA gene which is knocked in.
Cultures of colony 2 and wildtype yeast where grown in YPG (YP+2% glucose) overnight for chromosomal extraction using the MO BIO chromosomal extraction kit (protocol). A PCR reaction was performed on extracted genomic DNA of the grown strains, using an annealing gradient of 45, 55 and 65 C and 15 ng or 30 ng template DNA. Reactions AD, AB and CD where performed according to the conditions summarized in table 11. PCR product is put on gel and shown in figure 5. Here can be seen that colony 2 (B) shows both expected band length in the AB and CD reactions, but no bands in the AD reaction. Colony 1 (A) shows only bands in the AD reaction, so the knock-out was unsuccessful. Colony 3 (C) shows inconsistent bands in reactions AD (lane 5 and 7), BC (lane 10) and CD (lane 14 and 15), also not of the expected length.
Table 11 Taq PCR conditions for KO check.
| Repeats | Temperature | Duration | |
|---|---|---|---|
| 94 | Melting | 4:00 | |
| 35x | 94 | Melting | 0:30 |
| 45/55/65 | Annealing | 0:40 | |
| 72 | Elongation | 2:15 | |
| 72 | Elongation | 10:00 |
| GPA1 A conf CGTCCTTCTGCGTATTCTTCC |
| GPA1 D conf CCGAGTATTTACCAGGGAGAAG |
| KO B CGCCAAGGGTAGAGATCCTAAG |
| KO C CTTCACGCAGGATGACAGTTC |
Figure 5: 1% agarose gel in TAE, 40 min run on 100 V. PCR products of Genomic extracted DNA. Colony 1 (A), Colony 2 (B), and Colony 3 (C) are shown. In the picture can be seen: 1 DNA Smarladder, 2 AD reaction with 15 ng template and 45 C, 3 AD reaction with 15 ng template and 55 C, 4 AD reaction with 15 ng template and 65 C, 5 AD reaction with 30 ng template and 45 C, 6 AD reaction with 30 ng template and 55 C, 7 AD reaction with 30 ng template and 65 C, 8 AB reaction with 15 ng template and 45 C, 9 AB reaction with 15 ng template and 55 C, 10 AB reaction with 15 ng template and 65 C, 11 AB reaction with 30 ng template and 45 C, 12 AB reaction with 30 ng template and 55 C, 13 AB reaction with 30 ng template and 65 C, 14 CD reaction with 15 ng template and 45 C, 15 CD reaction with 15 ng template and 55 C, 16 CD reaction with 15 ng template and 65 C, 17 CD reaction with 30 ng template and 45 C, 18 CD reaction with 30 ng template and 55 C, 19 CD reaction with 30 ng template and 65 C, 20 smartladder.
We concluded that in colony 2 GPA1 has successfully been knocked out. The following test is to transform Fus1-GFP into this ?far1 ?gpa1 yeast and to see difference in fluorescence output when compared to ?far1 yeast strain when induced by pheromone alpha. Expected is that due to lack of alpha subunit of the pheromone receptor, no or less light signal is detected. A full description of the process can be seen BBa_K775005 and the R17-ODR10 receptor and output BBa_K775008 a fluorometer experiment was performed. After addition of the ligands OD600 and fluorescence were measured in time.
