Difference between revisions of "Team:CGU Taiwan/Parts"
| Line 221: | Line 221: | ||
<br><br> | <br><br> | ||
| − | <b>(1) Insert 5’HYG (BBa_K1955003), 3’UTR (BBa_K1955002), HA (BBa_K1955000) and OVA (BBa_K1955004) gBlocks into pSB1C3 vector:</b> | + | <b style="font-size:20px;">(1) Insert 5’HYG (BBa_K1955003), 3’UTR (BBa_K1955002), HA (BBa_K1955000) and OVA (BBa_K1955004) gBlocks into pSB1C3 vector:</b> |
| + | <br> | ||
<div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | <div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | ||
The biobrick parts, including 5’HYG, 3’UTR, HA and OVA, were synthesized directly by IDT. After receiving the synthesized parts, we used EcoRI and PstI to digest the parts and pSB1C3 backbone, then ligated and transformed the DNA samples into DH5a competent cells. According to the digestion and colony PCR results of the colony, all the parts were inserted into the pSB1C3 vector with the right length of DNA sequences, 5’HYG is 1446 bp, HA is 1700 bp, OVA is 2098 bp and 3’UTR is 774 bp.<br> | The biobrick parts, including 5’HYG, 3’UTR, HA and OVA, were synthesized directly by IDT. After receiving the synthesized parts, we used EcoRI and PstI to digest the parts and pSB1C3 backbone, then ligated and transformed the DNA samples into DH5a competent cells. According to the digestion and colony PCR results of the colony, all the parts were inserted into the pSB1C3 vector with the right length of DNA sequences, 5’HYG is 1446 bp, HA is 1700 bp, OVA is 2098 bp and 3’UTR is 774 bp.<br> | ||
| − | <img src="https://static.igem.org/mediawiki/2016/e/e9/CGU_Taiwan--bio5.jpg" width=550px height=300px style="border:2px black solid;border-radius:8px;"></img><br> | + | <img src="https://static.igem.org/mediawiki/2016/e/e9/CGU_Taiwan--bio5.jpg" width=550px height=300px style="border:2px black solid;border-radius:8px;"></img><br><br> |
(Fig. 1) pSB1C3-3’UTR, pSB1C3-5’HYG, pSB1C3-OVA checked by colony PCR and enzyme digestion | (Fig. 1) pSB1C3-3’UTR, pSB1C3-5’HYG, pSB1C3-OVA checked by colony PCR and enzyme digestion | ||
| − | <br> | + | <br><br> |
(A),(C) The pSB1C3-3’UTR and pSB1C3-OVA were transformed and the colonies were picked to perform colony PCR. The forward primer sequence was 5’- GAATTCGCGGCCGCTTCTAGAG-3’, which was in the prefix site. And the reverse primer sequence was 5’-CTGCAGCGGCCGCTACTAGTA-3’, which was in the suffix site. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. As the results, a 700~800 bp sequence was proliferated in pSB1C3-3’UTR, and a 2000~2500 bp sequence was proliferated from pSB1C3-OVA. (B) The pSB1C3-5’HYG was transformed and the colonies were picked and amplified in LB broth. pSB1C3-5’HYG plasmid was purified by miniprep, and digested with EcoRI and PstI for 4 hrs, then screened in 0.8% agarose gel by electrophoresis. The results showed a 2000 bp band of pSB1C3 and the 1500 bp 5’HYG.<br> | (A),(C) The pSB1C3-3’UTR and pSB1C3-OVA were transformed and the colonies were picked to perform colony PCR. The forward primer sequence was 5’- GAATTCGCGGCCGCTTCTAGAG-3’, which was in the prefix site. And the reverse primer sequence was 5’-CTGCAGCGGCCGCTACTAGTA-3’, which was in the suffix site. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. As the results, a 700~800 bp sequence was proliferated in pSB1C3-3’UTR, and a 2000~2500 bp sequence was proliferated from pSB1C3-OVA. (B) The pSB1C3-5’HYG was transformed and the colonies were picked and amplified in LB broth. pSB1C3-5’HYG plasmid was purified by miniprep, and digested with EcoRI and PstI for 4 hrs, then screened in 0.8% agarose gel by electrophoresis. The results showed a 2000 bp band of pSB1C3 and the 1500 bp 5’HYG.<br> | ||
| − | <img src="https://static.igem.org/mediawiki/2016/2/2d/CGU_Taiwan--bio6.jpg" width=450px height=200px style="border:2px black solid;border-radius:8px;"></img><br> | + | <img src="https://static.igem.org/mediawiki/2016/2/2d/CGU_Taiwan--bio6.jpg" width=450px height=200px style="border:2px black solid;border-radius:8px;"></img><br><br> |
(Fig. 2) The basic part checked by PCR | (Fig. 2) The basic part checked by PCR | ||
| − | <br> | + | <br><br> |
We used pSB1C3-5’HYG, pSB1C3-3’UTR, pSB1C3-HA, pSB1C3-OVA as template, to check the length of the inserts. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. | We used pSB1C3-5’HYG, pSB1C3-3’UTR, pSB1C3-HA, pSB1C3-OVA as template, to check the length of the inserts. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. | ||
</div> | </div> | ||
<br><br> | <br><br> | ||
| − | <b>(2) The construction of pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR (BBa_K1955006):</b> | + | <b style="font-size:20px;">(2) The construction of pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR (BBa_K1955006):</b> |
| + | <br> | ||
<div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | <div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | ||
| − | The pSB1C3-3’UTR was digested with EcoRI and XbaI, then the pSB1C3-HA and pSB1C3-OVA were digested with EcoRI and SpeI. After the purifying step, the pSB1C3-3’UTR was ligated with HA and OVA, then transformed after 16℃ overnight. The colony were checked with colony PCR, as the results, the HA-3’UTR would be about 2.6 kb (1774 bp +774 bp), and the OVA-3’UTR would be about 2.9 kb (2098 bp +774 bp).<br> | + | The pSB1C3-3’UTR was digested with EcoRI and XbaI, then the pSB1C3-HA and pSB1C3-OVA were digested with EcoRI and SpeI. After the purifying step, the pSB1C3-3’UTR was ligated with HA and OVA, then transformed after 16℃ overnight. The colony were checked with colony PCR, as the results, the HA-3’UTR would be about 2.6 kb (1774 bp +774 bp), and the OVA-3’UTR would be about 2.9 kb (2098 bp +774 bp).<br><br> |
<img src="https://static.igem.org/mediawiki/2016/8/89/CGU_Taiwan--bio15.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | <img src="https://static.igem.org/mediawiki/2016/8/89/CGU_Taiwan--bio15.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | ||
| − | <br> | + | <br><br> |
pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR checked by colony PCR | pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR checked by colony PCR | ||
| − | <br> | + | <br><br> |
The pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 2600 bp HA-3’ UTR and 2900 bp OVA-3’UTR were proliferated from pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR. | The pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 2600 bp HA-3’ UTR and 2900 bp OVA-3’UTR were proliferated from pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR. | ||
</div> | </div> | ||
<br><br> | <br><br> | ||
| − | <b>(3) The construction of pSB1C3-5’HYG-HA-3’UTR (BBa_K1955005) and pSB1C3-5’HYG-OVA-3’UTR (BBa_K1955006) : </b> | + | <b style="font-size:20px;">(3) The construction of pSB1C3-5’HYG-HA-3’UTR (BBa_K1955005) and pSB1C3-5’HYG-OVA-3’UTR (BBa_K1955006) : </b> |
| + | <br> | ||
<div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | <div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | ||
| − | The pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR were digested with EcoRI and XbaI, while the pSB1C3-5’UTR was digested with EcoRI and SpeI. The pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR and 5’UTR were purified by gel extraction, and ligated together. After the transformation step, we used colony PCR to check the correctness of the plasmid. The results showed that the approximately 4100 bp long 5’HYG-HA-3’UTR (1446 bp +1700 bp + 774 bp) and 4500 bp 5’HYG-HA-3’UTR (1446 bp + 2098 bp+ 774 bp) could be amplified from the plasmid, meaning that the pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR were finished in the step. In order to transfect the plasmid into leishmania by electroporation, we amplified the plasmid in 200 ml LB broth, and purified the DNA by midiprep.<br> | + | The pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR were digested with EcoRI and XbaI, while the pSB1C3-5’UTR was digested with EcoRI and SpeI. The pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR and 5’UTR were purified by gel extraction, and ligated together. After the transformation step, we used colony PCR to check the correctness of the plasmid. The results showed that the approximately 4100 bp long 5’HYG-HA-3’UTR (1446 bp +1700 bp + 774 bp) and 4500 bp 5’HYG-HA-3’UTR (1446 bp + 2098 bp+ 774 bp) could be amplified from the plasmid, meaning that the pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR were finished in the step. In order to transfect the plasmid into leishmania by electroporation, we amplified the plasmid in 200 ml LB broth, and purified the DNA by midiprep.<br><br> |
<img src="https://static.igem.org/mediawiki/2016/1/1c/CGU_Taiwan--bio7.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | <img src="https://static.igem.org/mediawiki/2016/1/1c/CGU_Taiwan--bio7.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | ||
| − | <br> | + | <br><br> |
pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR checked by colony PCR | pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR checked by colony PCR | ||
| − | <br> | + | <br><br> |
The pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 4100 bp 5’HYG-HA-3’UTR and 4500 bp 5’HYG-OVA-3’UTR were amplified from pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR. | The pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 4100 bp 5’HYG-HA-3’UTR and 4500 bp 5’HYG-OVA-3’UTR were amplified from pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR. | ||
</div> | </div> | ||
<br><br> | <br><br> | ||
| − | <b>(4) Construction of pSB1C3-2300 intron (BBa_K1955001):</b> | + | <b style="font-size:20px;">(4) Construction of pSB1C3-2300 intron (BBa_K1955001):</b> |
| + | <br> | ||
<div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | <div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | ||
Since the 2300 bp intrinsic sequence contained too many CG pairs, it couldn’t be synthesized. We used point mutation to change the nucleotide in the 2300 bp sequence, therefore, the sequence would be separated into 3 parts, the first and the second part were about 400~450 bp and the third part was approximately 1500 bp in length. Through the PCR, we could have these 3 parts amplified from p6.5 plasmid. We used the PCR-after-ligation strategy, ligating the first and second part together and performed PCR to amplify the sequence. Next, ligated the part 1 +part 2 sequence with part 3, and amplify the ligated parts with PCR again. The reason why we used the PCR-after-ligation strategy was because the ligation rate of the sequence was really low. However, although the parts of 2300 intron could be proliferated by PCR, we were unable to ligate the 3 parts together. The sequencing results of the 2300 intron always lost the second part, no matter what strategy we used in the construction. So, it turned out that we couldn’t put the 2300 intrinsic region into the final construction of our shuttle vector. | Since the 2300 bp intrinsic sequence contained too many CG pairs, it couldn’t be synthesized. We used point mutation to change the nucleotide in the 2300 bp sequence, therefore, the sequence would be separated into 3 parts, the first and the second part were about 400~450 bp and the third part was approximately 1500 bp in length. Through the PCR, we could have these 3 parts amplified from p6.5 plasmid. We used the PCR-after-ligation strategy, ligating the first and second part together and performed PCR to amplify the sequence. Next, ligated the part 1 +part 2 sequence with part 3, and amplify the ligated parts with PCR again. The reason why we used the PCR-after-ligation strategy was because the ligation rate of the sequence was really low. However, although the parts of 2300 intron could be proliferated by PCR, we were unable to ligate the 3 parts together. The sequencing results of the 2300 intron always lost the second part, no matter what strategy we used in the construction. So, it turned out that we couldn’t put the 2300 intrinsic region into the final construction of our shuttle vector. | ||
| − | <br> | + | <br><br> |
<img src="https://static.igem.org/mediawiki/2016/6/6f/CGU_Taiwan--bio16.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | <img src="https://static.igem.org/mediawiki/2016/6/6f/CGU_Taiwan--bio16.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | ||
| − | <br> | + | <br><br> |
All the parts of 2300 intron checked by PCR | All the parts of 2300 intron checked by PCR | ||
| − | <br> | + | <br><br> |
The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. Lane A to lane C were the three parts of 2300 intron, the first part was 400 bp, the second part was about 450 bp, and the third part was 1500 bp. Lane D was the ligation of part 1 + part 2, which would be approximately 800 bp. Lane E was the ligation of all three parts, which would be 2.3 kb in length. However, the second part would always be lost during the construction. | The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. Lane A to lane C were the three parts of 2300 intron, the first part was 400 bp, the second part was about 450 bp, and the third part was 1500 bp. Lane D was the ligation of part 1 + part 2, which would be approximately 800 bp. Lane E was the ligation of all three parts, which would be 2.3 kb in length. However, the second part would always be lost during the construction. | ||
</div> | </div> | ||
<br><br> | <br><br> | ||
| − | <b>(5) Construction of pSB1C3-5’HYG-GFP-3’UTR (BBa_K1955007)</b> | + | <b style="font-size:20px;">(5) Construction of pSB1C3-5’HYG-GFP-3’UTR (BBa_K1955007)</b> |
<div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | <div style="color:black;text-decoration:none;font-size:18px;margin-left:70px;"> | ||
Since we can’t detect the HA and OVA protein by western blotting after the pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR plasmid were transfected into leishmania. We decided to construct pSB1C3-5’HYG-GFP-3’UTR in order to prove if our leishmania shuttle vector could express the second protein or not. The GFP sequence came from BBa_E0040 in the vector pSB1A2. | Since we can’t detect the HA and OVA protein by western blotting after the pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR plasmid were transfected into leishmania. We decided to construct pSB1C3-5’HYG-GFP-3’UTR in order to prove if our leishmania shuttle vector could express the second protein or not. The GFP sequence came from BBa_E0040 in the vector pSB1A2. | ||
| − | <br> | + | <br><br> |
The pSB1C3-3’UTR was digested with EcoRI and XbaI, The pSB1A2-GFP and pSB1C3-5’HYG were digested with EcoRI and SpeI. After the purification, the pSB1C3-3’UTR was ligated with GFP and 5’HYG successively, then transformed into DH5a. The colonies were checked by colony PCR. The right length of GFP-3’UTR should be approximately 1.5 kb (720 bp +774 bp), while the 5’HYG-GFP-3’UTR should be about 3 kb (1446 bp +720 bp +774 bp). As the result, we knew that all the colonies contained the correct plasmid after the construction. The right colony of pSB1C3-5’HYG-GFP-3’UTR was picked and amplified in 200 ml LB broth, then the plasmid DNA was purified by midiprep.<br> | The pSB1C3-3’UTR was digested with EcoRI and XbaI, The pSB1A2-GFP and pSB1C3-5’HYG were digested with EcoRI and SpeI. After the purification, the pSB1C3-3’UTR was ligated with GFP and 5’HYG successively, then transformed into DH5a. The colonies were checked by colony PCR. The right length of GFP-3’UTR should be approximately 1.5 kb (720 bp +774 bp), while the 5’HYG-GFP-3’UTR should be about 3 kb (1446 bp +720 bp +774 bp). As the result, we knew that all the colonies contained the correct plasmid after the construction. The right colony of pSB1C3-5’HYG-GFP-3’UTR was picked and amplified in 200 ml LB broth, then the plasmid DNA was purified by midiprep.<br> | ||
<img src="https://static.igem.org/mediawiki/2016/b/bf/CGU_Taiwan--bio2.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | <img src="https://static.igem.org/mediawiki/2016/b/bf/CGU_Taiwan--bio2.jpg" width=550px height=400px style="border:2px black solid;border-radius:8px;"></img> | ||
| − | <br> | + | <br><br> |
pSB1C3-GFP-3’UTR and pSB1C3-5’HYG-GFP-3’UTR check by colony PCR | pSB1C3-GFP-3’UTR and pSB1C3-5’HYG-GFP-3’UTR check by colony PCR | ||
| − | <br> | + | <br><br> |
The PCR was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The GFP-3’UTR was about 1.5 kb in length, and the 5’HYG-GFP-3’UTR was about 3 kb. | The PCR was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The GFP-3’UTR was about 1.5 kb in length, and the 5’HYG-GFP-3’UTR was about 3 kb. | ||
</div> | </div> | ||
<br><br> | <br><br> | ||
| + | |||
| + | |||
| + | |||
</div> | </div> | ||
Revision as of 23:01, 19 October 2016
Leijuvant
Biobricks
(1) Insert 5’HYG (BBa_K1955003), 3’UTR (BBa_K1955002), HA (BBa_K1955000) and OVA (BBa_K1955004) gBlocks into pSB1C3 vector:
The biobrick parts, including 5’HYG, 3’UTR, HA and OVA, were synthesized directly by IDT. After receiving the synthesized parts, we used EcoRI and PstI to digest the parts and pSB1C3 backbone, then ligated and transformed the DNA samples into DH5a competent cells. According to the digestion and colony PCR results of the colony, all the parts were inserted into the pSB1C3 vector with the right length of DNA sequences, 5’HYG is 1446 bp, HA is 1700 bp, OVA is 2098 bp and 3’UTR is 774 bp.
(Fig. 1) pSB1C3-3’UTR, pSB1C3-5’HYG, pSB1C3-OVA checked by colony PCR and enzyme digestion
(A),(C) The pSB1C3-3’UTR and pSB1C3-OVA were transformed and the colonies were picked to perform colony PCR. The forward primer sequence was 5’- GAATTCGCGGCCGCTTCTAGAG-3’, which was in the prefix site. And the reverse primer sequence was 5’-CTGCAGCGGCCGCTACTAGTA-3’, which was in the suffix site. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. As the results, a 700~800 bp sequence was proliferated in pSB1C3-3’UTR, and a 2000~2500 bp sequence was proliferated from pSB1C3-OVA. (B) The pSB1C3-5’HYG was transformed and the colonies were picked and amplified in LB broth. pSB1C3-5’HYG plasmid was purified by miniprep, and digested with EcoRI and PstI for 4 hrs, then screened in 0.8% agarose gel by electrophoresis. The results showed a 2000 bp band of pSB1C3 and the 1500 bp 5’HYG.
(Fig. 2) The basic part checked by PCR
We used pSB1C3-5’HYG, pSB1C3-3’UTR, pSB1C3-HA, pSB1C3-OVA as template, to check the length of the inserts. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis.
(Fig. 1) pSB1C3-3’UTR, pSB1C3-5’HYG, pSB1C3-OVA checked by colony PCR and enzyme digestion
(A),(C) The pSB1C3-3’UTR and pSB1C3-OVA were transformed and the colonies were picked to perform colony PCR. The forward primer sequence was 5’- GAATTCGCGGCCGCTTCTAGAG-3’, which was in the prefix site. And the reverse primer sequence was 5’-CTGCAGCGGCCGCTACTAGTA-3’, which was in the suffix site. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. As the results, a 700~800 bp sequence was proliferated in pSB1C3-3’UTR, and a 2000~2500 bp sequence was proliferated from pSB1C3-OVA. (B) The pSB1C3-5’HYG was transformed and the colonies were picked and amplified in LB broth. pSB1C3-5’HYG plasmid was purified by miniprep, and digested with EcoRI and PstI for 4 hrs, then screened in 0.8% agarose gel by electrophoresis. The results showed a 2000 bp band of pSB1C3 and the 1500 bp 5’HYG.
(Fig. 2) The basic part checked by PCR
We used pSB1C3-5’HYG, pSB1C3-3’UTR, pSB1C3-HA, pSB1C3-OVA as template, to check the length of the inserts. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis.
(2) The construction of pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR (BBa_K1955006):
The pSB1C3-3’UTR was digested with EcoRI and XbaI, then the pSB1C3-HA and pSB1C3-OVA were digested with EcoRI and SpeI. After the purifying step, the pSB1C3-3’UTR was ligated with HA and OVA, then transformed after 16℃ overnight. The colony were checked with colony PCR, as the results, the HA-3’UTR would be about 2.6 kb (1774 bp +774 bp), and the OVA-3’UTR would be about 2.9 kb (2098 bp +774 bp).
pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR checked by colony PCR
The pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 2600 bp HA-3’ UTR and 2900 bp OVA-3’UTR were proliferated from pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR.
pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR checked by colony PCR
The pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 2600 bp HA-3’ UTR and 2900 bp OVA-3’UTR were proliferated from pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR.
(3) The construction of pSB1C3-5’HYG-HA-3’UTR (BBa_K1955005) and pSB1C3-5’HYG-OVA-3’UTR (BBa_K1955006) :
The pSB1C3-HA-3’UTR and pSB1C3-OVA-3’UTR were digested with EcoRI and XbaI, while the pSB1C3-5’UTR was digested with EcoRI and SpeI. The pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR and 5’UTR were purified by gel extraction, and ligated together. After the transformation step, we used colony PCR to check the correctness of the plasmid. The results showed that the approximately 4100 bp long 5’HYG-HA-3’UTR (1446 bp +1700 bp + 774 bp) and 4500 bp 5’HYG-HA-3’UTR (1446 bp + 2098 bp+ 774 bp) could be amplified from the plasmid, meaning that the pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR were finished in the step. In order to transfect the plasmid into leishmania by electroporation, we amplified the plasmid in 200 ml LB broth, and purified the DNA by midiprep.
pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR checked by colony PCR
The pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 4100 bp 5’HYG-HA-3’UTR and 4500 bp 5’HYG-OVA-3’UTR were amplified from pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR.
pSB1C3-HA-3’UTR, pSB1C3-OVA-3’UTR checked by colony PCR
The pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR were transformed and the colonies were picked to perform colony PCR. The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The 4100 bp 5’HYG-HA-3’UTR and 4500 bp 5’HYG-OVA-3’UTR were amplified from pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR.
(4) Construction of pSB1C3-2300 intron (BBa_K1955001):
Since the 2300 bp intrinsic sequence contained too many CG pairs, it couldn’t be synthesized. We used point mutation to change the nucleotide in the 2300 bp sequence, therefore, the sequence would be separated into 3 parts, the first and the second part were about 400~450 bp and the third part was approximately 1500 bp in length. Through the PCR, we could have these 3 parts amplified from p6.5 plasmid. We used the PCR-after-ligation strategy, ligating the first and second part together and performed PCR to amplify the sequence. Next, ligated the part 1 +part 2 sequence with part 3, and amplify the ligated parts with PCR again. The reason why we used the PCR-after-ligation strategy was because the ligation rate of the sequence was really low. However, although the parts of 2300 intron could be proliferated by PCR, we were unable to ligate the 3 parts together. The sequencing results of the 2300 intron always lost the second part, no matter what strategy we used in the construction. So, it turned out that we couldn’t put the 2300 intrinsic region into the final construction of our shuttle vector.
All the parts of 2300 intron checked by PCR
The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. Lane A to lane C were the three parts of 2300 intron, the first part was 400 bp, the second part was about 450 bp, and the third part was 1500 bp. Lane D was the ligation of part 1 + part 2, which would be approximately 800 bp. Lane E was the ligation of all three parts, which would be 2.3 kb in length. However, the second part would always be lost during the construction.
All the parts of 2300 intron checked by PCR
The PCR reaction was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. Lane A to lane C were the three parts of 2300 intron, the first part was 400 bp, the second part was about 450 bp, and the third part was 1500 bp. Lane D was the ligation of part 1 + part 2, which would be approximately 800 bp. Lane E was the ligation of all three parts, which would be 2.3 kb in length. However, the second part would always be lost during the construction.
(5) Construction of pSB1C3-5’HYG-GFP-3’UTR (BBa_K1955007)
Since we can’t detect the HA and OVA protein by western blotting after the pSB1C3-5’HYG-HA-3’UTR and pSB1C3-5’HYG-OVA-3’UTR plasmid were transfected into leishmania. We decided to construct pSB1C3-5’HYG-GFP-3’UTR in order to prove if our leishmania shuttle vector could express the second protein or not. The GFP sequence came from BBa_E0040 in the vector pSB1A2.
The pSB1C3-3’UTR was digested with EcoRI and XbaI, The pSB1A2-GFP and pSB1C3-5’HYG were digested with EcoRI and SpeI. After the purification, the pSB1C3-3’UTR was ligated with GFP and 5’HYG successively, then transformed into DH5a. The colonies were checked by colony PCR. The right length of GFP-3’UTR should be approximately 1.5 kb (720 bp +774 bp), while the 5’HYG-GFP-3’UTR should be about 3 kb (1446 bp +720 bp +774 bp). As the result, we knew that all the colonies contained the correct plasmid after the construction. The right colony of pSB1C3-5’HYG-GFP-3’UTR was picked and amplified in 200 ml LB broth, then the plasmid DNA was purified by midiprep.
pSB1C3-GFP-3’UTR and pSB1C3-5’HYG-GFP-3’UTR check by colony PCR
The PCR was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The GFP-3’UTR was about 1.5 kb in length, and the 5’HYG-GFP-3’UTR was about 3 kb.
The pSB1C3-3’UTR was digested with EcoRI and XbaI, The pSB1A2-GFP and pSB1C3-5’HYG were digested with EcoRI and SpeI. After the purification, the pSB1C3-3’UTR was ligated with GFP and 5’HYG successively, then transformed into DH5a. The colonies were checked by colony PCR. The right length of GFP-3’UTR should be approximately 1.5 kb (720 bp +774 bp), while the 5’HYG-GFP-3’UTR should be about 3 kb (1446 bp +720 bp +774 bp). As the result, we knew that all the colonies contained the correct plasmid after the construction. The right colony of pSB1C3-5’HYG-GFP-3’UTR was picked and amplified in 200 ml LB broth, then the plasmid DNA was purified by midiprep.
pSB1C3-GFP-3’UTR and pSB1C3-5’HYG-GFP-3’UTR check by colony PCR
The PCR was performed with Taq polymerase, and screened in 0.8% agarose gel by electrophoresis. The GFP-3’UTR was about 1.5 kb in length, and the 5’HYG-GFP-3’UTR was about 3 kb.
