Difference between revisions of "Team:Gifu/result-page"
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<b>Fig.1 As a result of qualitative experiment of Circular mRNA</b></div> | <b>Fig.1 As a result of qualitative experiment of Circular mRNA</b></div> | ||
− | <p> | + | <p>1:normal(iGEM Gifu 2014) 2:outside complementarity 3:inside complementarityⅠ 4:inside complementarityⅡ |
</p> | </p> | ||
<p>a…To detect the sequence of the circular mRNA in the cDNA derived from the RNA after RNaseR processing.</p> | <p>a…To detect the sequence of the circular mRNA in the cDNA derived from the RNA after RNaseR processing.</p> | ||
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− | + | <p>See the line e,f → RNA is not detected by the electrophoresis, namely, DNA does not contaminate.</p> | |
− | See the line e,f → RNA is not detected by the electrophoresis, namely, DNA does not contaminate. | + | <p>See the line b,d → Linear mRNA is cleaved by exoribonuclease.</p> |
− | See the line b,d → Linear mRNA is cleaved by exoribonuclease. | + | <p>See the line a,c → mRNA is not cleaved by exoribonuclease.</p> |
− | See the line a,c → mRNA is not cleaved by exoribonuclease. | + | <p>From the above, the circular mRNA exists in all samples.</p> |
− | From the above, the circular mRNA exists in all samples. | + | |
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− | + | ||
− | </p> | + | |
<p> | <p> |
Revision as of 19:01, 18 September 2015
normal | outside | insideⅠ | insideⅡ | |
---|---|---|---|---|
Efficiency of circularization (relativity value) | 1.00 | 2.05 | 1.22 | 1.34 |
FUNCTION
We made 7 kinds of linker in this experiment.
We made parts which have these sequence of linker in the downstream of the 3’ side of the intron [BBa_K1332005] or the upstream of the 5’ side of the intron without stop codon [BBa_K1332003].
We constructed plasmids like following it.
In case of inserting these plasmid into E. coli, the following circular mRNA is expressed and the long chain protein is synthesized.
We inserted these plasmid into an E.coli and made it synthesize proteins and did SDS-PAGE using this proteins. If the protein is not boiled, we can do SDS-PAGE keeping it fluorescence because RFP’s structure is strong. Therefore we applied samples that were not boiled.
Fig.4 Fluorescence of protein before dying by CBB
Fig.5 after dying by CBB
Fig.6 Overlapping Fig.4 and Fig.5
No. | generator |
---|---|
A | R0010+ B0034+ K1332001+ B0015 |
B | BBa_K1332011 |
C | BBa_K1859027 |
D | BBa_K1859028 |
E | BBa_K1859020 |
F | BBa_K1859021 |
G | BBa_K1859022 |
H | BBa_K1859023 |
I | BBa_K1859023 |
J | BBa_K1859025 |
K | BBa_K1859024 |
There was not fluorescence at the place of long chain protein. We found that long chain protein didn’t have a function.
Reason of why [BBa_K1859020] and [BBa_K1859022] don’t synthesize the long chain protein
We made prediction of synthesized mRNA’s secondary structure.
We can see the mRNA which is not to synthesize a long chain protein (BBa_K1859020 and BBa_K1859022) forms hydrogen bonds in downstream of the ribosome binding site. It is assumed that these binds prevent mRNA from starting to be translated.