Difference between revisions of "Team:Gifu/project/"
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− | <p> The group I intron in td gene of T4 phage has self-splicing mechanism. The self-splicing is a mechanism that circularizes the intron and connects exons. This is catalyzed by several base sequences of the ends of the introns as a ribozyme. We permuted exons and introns with the mechanism and attempted an exon circularization. So we constructed mRNA circularization devices in last year. </p> | + | <p> The group I intron in <i>td</i> gene of T4 phage has self-splicing mechanism. The self-splicing is a mechanism that circularizes the intron and connects exons. This is catalyzed by several base sequences of the ends of the introns as a ribozyme. We permuted exons and introns with the mechanism and attempted an exon circularization. So we constructed mRNA circularization devices in last year. </p> |
− | <p> We explain the circularization mechanism of group I intron with td gene of T4 phage as an example. Td gene consists of an upstream exon, an upstream intron, an ORF, a downstream intron and a downstream exon. This mechanism is divided into 3 steps. As the first step, a nucleophilic attack by a guanosine separates the upstream exon from the upstream intron and then the guanosine bonds to the 5’ end of the upstream intron. | + | <p> We explain the circularization mechanism of group I intron with <i>td</i> gene of T4 phage as an example. <i>Td</i> gene consists of an upstream exon, an upstream intron, an ORF, a downstream intron and a downstream exon. This mechanism is divided into 3 steps. As the first step, a nucleophilic attack by a guanosine separates the upstream exon from the upstream intron and then the guanosine bonds to the 5’ end of the upstream intron. |
As the second step, the downstream exon is separated from the downstream intron by a nucleophilic attack. The nucleophilic attack takes place by a hydroxy group at the 3’ end of the upstream exon. (Figure 1)<br> | As the second step, the downstream exon is separated from the downstream intron by a nucleophilic attack. The nucleophilic attack takes place by a hydroxy group at the 3’ end of the upstream exon. (Figure 1)<br> | ||
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− | We can use the group I intron self-splicing mechanism in td gene of T4 phage to circularize mRNA. The group I intron self-splicing is a mechanism that circularizes an intron and connects exons. It occurs after transcription. The self-splicing is catalyzed by several base sequences of the ends of introns as a ribozyme. We permuted exons and introns with the mechanism and attempted an exon circularization. So we constructed mRNA circularization devices. We induced a protein coding sequence and them into <i>E. coli</i>. We created circular mRNA and synthesized massive long-chain protein with it. | + | We can use the group I intron self-splicing mechanism in <i>td</i> gene of T4 phage to circularize mRNA. The group I intron self-splicing is a mechanism that circularizes an intron and connects exons. It occurs after transcription. The self-splicing is catalyzed by several base sequences of the ends of introns as a ribozyme. We permuted exons and introns with the mechanism and attempted an exon circularization. So we constructed mRNA circularization devices. We induced a protein coding sequence and them into <i>E. coli</i>. We created circular mRNA and synthesized massive long-chain protein with it. |
</p> | </p> | ||
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− | <p> The PIE method is shown below(Figure 5). First, we picked out the intron and splice sites in the exon from td gene in T4 phage. Second, sandwich the sequence that you want to circularize between preceding fragments. | + | <p> The PIE method is shown below(Figure 5). First, we picked out the intron and splice sites in the exon from <i>td</i> gene in T4 phage. Second, sandwich the sequence that you want to circularize between preceding fragments. |
</p> | </p> | ||
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<h4> <font size="5" face="Century"> LAST YEAR</font> </h4> | <h4> <font size="5" face="Century"> LAST YEAR</font> </h4> | ||
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− | <p> Last year, we confirmed that making mRNA circular in E.coli by PIE method and synthesizing long-chain protein. (<a href= "https://2014.igem.org/Team:Gifu" style="text-decoration:none;" style="text-decoration:none;" >2014 Team Gifu</a>) </p> <br><br> | + | <p> Last year, we confirmed that making mRNA circular in <i>E. coli</i> by PIE method and synthesizing long-chain protein. (<a href= "https://2014.igem.org/Team:Gifu" style="text-decoration:none;" style="text-decoration:none;" >2014 Team Gifu</a>) </p> <br><br> |
<p><b>Make-circular mRNA</b><br> | <p><b>Make-circular mRNA</b><br> | ||
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Qualitative test of long-chain protein was conducted by using SDS-PAGE. | Qualitative test of long-chain protein was conducted by using SDS-PAGE. | ||
− | We found huge protein by SDS-PAGE when crushing E.coli had circular mRNA. | + | We found huge protein by SDS-PAGE when crushing <i>E. coli</i> had circular mRNA. |
In addition, we found that the protein was derived from RFP by Western blot. | In addition, we found that the protein was derived from RFP by Western blot. | ||
Thus, we concluded circular mRNA made long-chain protein. | Thus, we concluded circular mRNA made long-chain protein. | ||
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</p> | </p> | ||
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+ | <img src="https://static.igem.org/mediawiki/2014/0/0e/RFPGIFU.png" width="360" height="270"></img> | ||
<img src="https://static.igem.org/mediawiki/2015/5/5f/Gifu-fig-fig-fig.png" width="360" height="270"></img> | <img src="https://static.igem.org/mediawiki/2015/5/5f/Gifu-fig-fig-fig.png" width="360" height="270"></img> | ||
− | + | <br> | |
− | <b>Fig.9 The protein has the fluorescence, or not. Fig.10 Efficiency of circularization</b> | + | <b>Fig.9 The protein has the fluorescence, or not. |
+ | Fig.10 Efficiency of circularization </b> | ||
</p> | </p> | ||
<p> | <p> |
Latest revision as of 19:28, 18 September 2015