Team:HokkaidoU Japan/Projects/Length/Overview

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In this study, we made many kinds of anti-sense which have different lengths, and are investigated to have different repression efficiency. These anti-sense constructs themselves is not useful for you. However our information is very useful. In our way, you can create the needed anti-sense. We expect this results will help you decide anti-sense sequences. It is our satisfaction that our study tells scientists and iGEMers that repressing by anti-sense is easy and acurate.</p>
In this study, we made many kinds of anti-sense which have different lengths, and are investigated to have different repression efficiency. These anti-sense constructs themselves is not useful for you. However our information is very useful. In our way, you can create the needed anti-sense. We expect this results will help you decide anti-sense sequences. It is our satisfaction that our study tells scientists and iGEMers that repressing by anti-sense is easy and acurate.</p>
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    <ol class="citation-list">
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      <li id="cite-1">N Nakashima <i>et al.</i> (2006) Paired termini stabilize antisense RNAs and enhance conditional gene silencing in <i>Escherichia coli</i>. Nucleic Acids Res 34: 20 e138</li>
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    </ol>
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<h1 id="Method"> How to synthesize anti-sense constructs</h1>
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<p>
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Anti-sense fragments were synthesized based on BioBrick by PCR. Forward primers are common (XhoI-Ptet (-10)). Each reverse primers are different (as90 NcoI, as120 NcoI) (Fig. 1). As90 is the anti-sense that covers 90 bp of mRNA, and as 120 is the anti-sense that covers 120 bp of mRNA (complement RBS and a part of mRFP sequence.) Because of these, we got various length anti-senses. The sides of antisense fragment have restriction enzymes XhoI, NcoI sites. </p>
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<div class="fig fig800">
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<img src="https://static.igem.org/mediawiki/2014/1/12/HokkaidoU_length_Length_method1.png">
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<div>Fig. 1 Synthesizing anti-sense by PCR</div>
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<div class="fig fig400" >
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<img src="https://static.igem.org/mediawiki/2014/6/6f/HokkaidoU_length_Method2.png">
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<div>Fig. 2 Ligate the anti-sense fragment with H-stem vector</div>
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</div>
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<p>
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<!
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<p>
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After we finished synthesizing pre anti-sense fragments, we cut them and H-stem vector (our anti-sense expression vector) by XhoI and NcoI. Finally, we ligated them. The anti-sense constructs are complete because pre anti-sense fragments are ligated reversely. Then, we measured their repression efficiencies. Therefore, we got anti-sense fragment, as90 and as120. As the same way, we made as30, as60 in H-Stem System and Anti-sense B0034 examination. We performed repression examination by using their 4 anti-sense constructs.
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</p>
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<div class="clearfix">
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</div>
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<h1>How to assay</h1>
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<p>We selected mRFP for the target gene. We used fluorophotometer to measure how anti-sense worked. The colonies transformed by anti-sense constructs and target gene was used for assay.</p>
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<ol>
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<li>To cultivate the colony in 4 mL LB culture for about 20 hours</li>
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<li>To control turbidity up to 0.1 at OD600</li>
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<li>To cultivate the colony in 2 mL M9ZB culture for 9 hours (100mM IPTG induces antisense constructs, addition 20 uL)</li>
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<li>To measure fluorescence after 9 hour</li>
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</ol>
</div>
</div>
</div>
</div>

Latest revision as of 16:06, 15 October 2014

Overview

It is known that the length of anti-sense is related to its repression efficiency (N Nakashima et al., 2006[1]), but the detail of relations between the length of anti-sense and their repression efficiency is still unclear. In this study, we made different lengths of anti-sense sequence (Fig. 1), and measured it's repression efficiencies.

Fig. 1 Each anti-sense repress mRNA.

Our experiments of anti-sense RNA (asRNA) sequence and it's length reveals the relation. Thus our findings will be a clue for other iGEMers that wants to design their own anti-sense sequence.

Introduction

In repressing gene by anti-sense, it is important to choose anti-sense length. However, it is difficult to decide anti-sense length. Theoretically, even if they are too long, it doesn’t repress target RNA effectively. The reason is because RNA polymerase takes a lot of time to synthesize them, and the diffusion rate of them is also made to be low. However, too short asRNA also has some problem. The short anti-sense cannot bind to the specific part of mRNA because it has too short complementary sequences of target RNA. In the industrial and academic places, it is hoped to use anti-sense that has suitable repression efficiency. For example, you can create knock down recombinant organisms easily by using strong anti-sense, and in iGEM, you can make a bio-devices which has a complicated gene network and require fine-tuned gene expression. Gene’s expression is not only ON or OFF. As stated above, each cases need each repression efficiency. Researchers currently try to change anti-sense repression efficiency by changing anti-sense’s binding sequence. However, it is found that this method is difficult.

In this study, we made many kinds of anti-sense which have different lengths, and are investigated to have different repression efficiency. These anti-sense constructs themselves is not useful for you. However our information is very useful. In our way, you can create the needed anti-sense. We expect this results will help you decide anti-sense sequences. It is our satisfaction that our study tells scientists and iGEMers that repressing by anti-sense is easy and acurate.



  1. N Nakashima et al. (2006) Paired termini stabilize antisense RNAs and enhance conditional gene silencing in Escherichia coli. Nucleic Acids Res 34: 20 e138

How to synthesize anti-sense constructs

Anti-sense fragments were synthesized based on BioBrick by PCR. Forward primers are common (XhoI-Ptet (-10)). Each reverse primers are different (as90 NcoI, as120 NcoI) (Fig. 1). As90 is the anti-sense that covers 90 bp of mRNA, and as 120 is the anti-sense that covers 120 bp of mRNA (complement RBS and a part of mRFP sequence.) Because of these, we got various length anti-senses. The sides of antisense fragment have restriction enzymes XhoI, NcoI sites.

Fig. 1 Synthesizing anti-sense by PCR
Fig. 2 Ligate the anti-sense fragment with H-stem vector

After we finished synthesizing pre anti-sense fragments, we cut them and H-stem vector (our anti-sense expression vector) by XhoI and NcoI. Finally, we ligated them. The anti-sense constructs are complete because pre anti-sense fragments are ligated reversely. Then, we measured their repression efficiencies. Therefore, we got anti-sense fragment, as90 and as120. As the same way, we made as30, as60 in H-Stem System and Anti-sense B0034 examination. We performed repression examination by using their 4 anti-sense constructs.

How to assay

We selected mRFP for the target gene. We used fluorophotometer to measure how anti-sense worked. The colonies transformed by anti-sense constructs and target gene was used for assay.

  1. To cultivate the colony in 4 mL LB culture for about 20 hours
  2. To control turbidity up to 0.1 at OD600
  3. To cultivate the colony in 2 mL M9ZB culture for 9 hours (100mM IPTG induces antisense constructs, addition 20 uL)
  4. To measure fluorescence after 9 hour