Difference between revisions of "Part:BBa K1777016"

 
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__NOTOC__
 
__NOTOC__
 
<partinfo>BBa_K1777016 short</partinfo>
 
<partinfo>BBa_K1777016 short</partinfo>
  
This device has two inverted repeat sequence and can produce circular mir-21 sponge.
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{| style="color:black" cellpadding="6" cellspacing="1" border="2" align="right"
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! colspan="2" style="background:#FFBF00;"|DRS-(β-globin SA)-(miR-21 binding site)6-(β-globin SD)-RRS
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|-
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|'''Function'''
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|Cyclized RNA based on sequence
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|-
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|'''Use in'''
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|Mammalian cells
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|-
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|'''RFC standard'''
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|[https://parts.igem.org/Help:Assembly_standard_10 RFC 10]
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|-
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|'''Backbone'''
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|pSB1C3<br>
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|-
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|'''Submitted by'''
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|[http://2015.igem.org/Team:Fudan Fudan 2015]
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|}
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The Fudan iGEM team 2015 designed the device with two inverted repeat sequence which can produce circular mir-21 sponge. We nicknamed it "Ouroboros".The ouroboros or uroboros (/jʊərɵˈbɒrəs/; /ɔːˈrɒbɔrəs/, from the Greek οὐροβόρος ὄφις tail-devouring snake) is an ancient symbol depicting a serpent or dragon eating its own tail.
 +
Just like the ouroboros of myth, our Ouroboros cyclized itself by 'biting' its own. This is the plan A of our cyclizing device. We used the inverted repeat sequence, which is inserted into the flanking intron of the circularizing sequence.<br>
 +
We generate long inverted repeat sequence of 400bp and insert this sequence into the flanking intron of the circularizing exon. We choose the inserted sequence which have higher binding affinity to increase the cyclization efficiency. The flanking intron is β-globin intron1, which can improve the expression level of our device RNA, and provide long linker for the back-splicing mechanism.<br>
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[[File:Overview_of_the_construct_Ouroboros_igem_2015.png | 700 px |center]]<br>
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'''Figure 1: Construct design.''' The Ouroboros contains inverted repeat sequences and 6 miR-21 binding sites. Here, DRS means direct repeat sequence and RRS means reverse-complementary repeat sequence.
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The prototype of Ouroboros is to generate circRNA sponge to regulate oncomiRs, and this is based on the long half-life time of circRNA. In order to validate this assumption, we designed circRNA degradation experiment to measure circRNA half-life time.In this experiment, we use our device to cyclize the RNA and simulate the prototype in which the Ouroboros are used as research device.<br>
 +
The circularizing exon have 6 mir-21 binding site, which is reported to be the most efficient number for miRNA sponges. The circularizing exon is constructed by overlap PCR, and the binding site is designed to have the highest binding affinity. <br>
 +
In order to build a tool box, we are synthesize the inverted sequence and the circularizing sequence separately, and finally combine these two parts together. Other than mir-21 sponge, we also designed mir-17 sponge circularizing exon. Our toolbox will finally able to regulate different kinds of miRNAs, and facilitate the reseach and health care issues related to miRNA.<br>
 +
To support our testing experiment, we designed a reporter Luciferase device. We inserted two mir-21 binding site to the 3’-UTR of the Luciferase, and it can report the mir-21 concentration by the intense of fluorescent. <br>
  
<!-- Add more about the biology of this part here
 
===Usage and Biology===
 
  
<!-- -->
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===Proof of function===
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We experimentally validate that our device can accelerate the formation of cirRNA. We used pZW1 as the backbone vector firstly and HEK-293T cells to testing this device. We extracted the total RNA of cells and reverse-transcripted all the RNA into cDNA via Reverse Transcription-PCR (RT-PCR). To proof the RNA-circlization, we designed specific primers.<br>
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[[File:IDT.jpg| 700px |center]]<br>
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'''Figure 2: Identification of circRNA via qPCR.'''Only circRNA can be expanded by PCR with samples in the same mass and be detected by gel electrophoresis. The result shows our device can cyclize the specific RNA sequence efficiently.<br>
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[[File:pZW1circ.png|center]]<br>
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'''Figure 3: Circlization test by PCR.''' The 400bp and 300bp markers are indicated in lane 1. Control groups (lane 2 and 3) in which cells was transfected by pZW1 vector without insert sequence cannot cyclize RNA, while the target bands with 356bp can be detected in pZW1-circ groups (i.e. experiment group, lane 4, 5, 6 and 7).<br>
 +
In order to test the results precisely and quantitatively, the cDNA was identifued via real-time quantitative PCR (qPCR). Here is results.<br>
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[[File:pZW1circ_qPCR.jpg|center]]<br>
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'''Figure 4: Circlization test by qPCR.''' Here exists significant difference between control groups and pZW1-circ groups.
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<br>
 
<span class='h3bb'>Sequence and Features</span>
 
<span class='h3bb'>Sequence and Features</span>
 
<partinfo>BBa_K1777016 SequenceAndFeatures</partinfo>
 
<partinfo>BBa_K1777016 SequenceAndFeatures</partinfo>

Latest revision as of 21:38, 23 September 2015

Device to produce circRNA

DRS-(β-globin SA)-(miR-21 binding site)6-(β-globin SD)-RRS
Function Cyclized RNA based on sequence
Use in Mammalian cells
RFC standard RFC 10
Backbone pSB1C3
Submitted by [http://2015.igem.org/Team:Fudan Fudan 2015]

The Fudan iGEM team 2015 designed the device with two inverted repeat sequence which can produce circular mir-21 sponge. We nicknamed it "Ouroboros".The ouroboros or uroboros (/jʊərɵˈbɒrəs/; /ɔːˈrɒbɔrəs/, from the Greek οὐροβόρος ὄφις tail-devouring snake) is an ancient symbol depicting a serpent or dragon eating its own tail. Just like the ouroboros of myth, our Ouroboros cyclized itself by 'biting' its own. This is the plan A of our cyclizing device. We used the inverted repeat sequence, which is inserted into the flanking intron of the circularizing sequence.
We generate long inverted repeat sequence of 400bp and insert this sequence into the flanking intron of the circularizing exon. We choose the inserted sequence which have higher binding affinity to increase the cyclization efficiency. The flanking intron is β-globin intron1, which can improve the expression level of our device RNA, and provide long linker for the back-splicing mechanism.

Overview of the construct Ouroboros igem 2015.png

Figure 1: Construct design. The Ouroboros contains inverted repeat sequences and 6 miR-21 binding sites. Here, DRS means direct repeat sequence and RRS means reverse-complementary repeat sequence.

The prototype of Ouroboros is to generate circRNA sponge to regulate oncomiRs, and this is based on the long half-life time of circRNA. In order to validate this assumption, we designed circRNA degradation experiment to measure circRNA half-life time.In this experiment, we use our device to cyclize the RNA and simulate the prototype in which the Ouroboros are used as research device.
The circularizing exon have 6 mir-21 binding site, which is reported to be the most efficient number for miRNA sponges. The circularizing exon is constructed by overlap PCR, and the binding site is designed to have the highest binding affinity.
In order to build a tool box, we are synthesize the inverted sequence and the circularizing sequence separately, and finally combine these two parts together. Other than mir-21 sponge, we also designed mir-17 sponge circularizing exon. Our toolbox will finally able to regulate different kinds of miRNAs, and facilitate the reseach and health care issues related to miRNA.
To support our testing experiment, we designed a reporter Luciferase device. We inserted two mir-21 binding site to the 3’-UTR of the Luciferase, and it can report the mir-21 concentration by the intense of fluorescent.


Proof of function

We experimentally validate that our device can accelerate the formation of cirRNA. We used pZW1 as the backbone vector firstly and HEK-293T cells to testing this device. We extracted the total RNA of cells and reverse-transcripted all the RNA into cDNA via Reverse Transcription-PCR (RT-PCR). To proof the RNA-circlization, we designed specific primers.

IDT.jpg

Figure 2: Identification of circRNA via qPCR.Only circRNA can be expanded by PCR with samples in the same mass and be detected by gel electrophoresis. The result shows our device can cyclize the specific RNA sequence efficiently.

PZW1circ.png

Figure 3: Circlization test by PCR. The 400bp and 300bp markers are indicated in lane 1. Control groups (lane 2 and 3) in which cells was transfected by pZW1 vector without insert sequence cannot cyclize RNA, while the target bands with 356bp can be detected in pZW1-circ groups (i.e. experiment group, lane 4, 5, 6 and 7).
In order to test the results precisely and quantitatively, the cDNA was identifued via real-time quantitative PCR (qPCR). Here is results.

PZW1circ qPCR.jpg

Figure 4: Circlization test by qPCR. Here exists significant difference between control groups and pZW1-circ groups.
Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 462
    Illegal XhoI site found at 833
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI.rc site found at 804