Difference between revisions of "Part:BBa K3229304"
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<partinfo>BBa_K3229304 short</partinfo>
 
<partinfo>BBa_K3229304 short</partinfo>
  
This part was constructed to certify the bidirectional transcription from mcyA/D promoter. Therefore we put a composite GFP which coded by two identical genes. Originally the mcyA/D promoter located between the mcyABC and mcyDEFGHIJ, thus the gene expression can occur in both ways. These genes were replaced with the two parts of the composite GFP genes, GFP2 located in the 3' direction and GFP1 is in 5' direction from the promoter sequence. When microcystin toxin is present it induces the synthesis of both of the composite GFP parts due to the phenomenon called autoinduction. The synthesized protein parts bond together and form a functional GFP that glows under UV light. Due to this method, we are able to perceive the appearance of the microcystin toxin and test the bidirectional transcription from the mcyA/D promoter. We can measure the amount of the emitted green light by fluorescence microscope.
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This part is constructed to certify the bidirectional transcription from McyD promoter. Normally microcystin toxin-forming protein genes (McyABC and McyDEFGHIJ) are located next to the McyD promoter in both 5’-3 and 3’-5’ directions. When microcystin toxin is present, it enhances the synthesis of these proteins, thus promotes more toxin production. This phenomenon is called autoinduction. 
The composite part consists of a reversed terminator sequence, the reversed sequence of the original GFP1, a reversed RBS, the mcyA/D promoter, another RBS, the GFP2 sequence, a terminator sequence, a noncoding sequence (ATATATATAT) and a BamHI restriction site (GGATCC).
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We used the reversed sequences of the original sequences we found on the registry pages. These parts were made by GeneiousPrime.
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We replaced the toxin-producing genes with a composite GFP, which consists of two parts. We put one part in the 3' direction and the other one in the 5' direction from the McyD promoter. When the two parts are synthesized at the same time they connect together to form an active GFP that glows. Thus The transformed bacteria that has the insert can only glow under UV light if the bidirectional transcription works. This construct consists of the McyD promoter, an RBS, GFP2 and a terminator sequence in the 3' direction from the promoter and a reverse RBS, a reverse GFP1 and a reverse terminator sequence in the 5' direction from the promoter.
The uploaded part does NOT contain the non-coding and the BamHI sequence. The non-coding sequence and the BamHI are required to insert the construct into a shuttle vector which we can transform the plasmid into both Escherichia coli and Microcystis aeruginosa.
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 +
(kép a konstruktról)
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 +
For cloning we used the Zero Blunt TOPO PCR Cloning Kit from Thermo Fischer Scientific (https://www.thermofisher.com/order/catalog/product/450245?tsid=Email_POE_OC_OrderConfirm%20%0D%20_SKULINK#/450245?tsid=Email_POE_OC_OrderConfirm%20%0D%20_SKULINK). It uses a vector, called pCR-Blunt II-TOPO. The ligation of the vector and insert is done by topoisomerase enzymes, which are connected to the ends of the linearised vector. At the 5’ side of the cleavage there is a Plac promoter, which starts transcription from lacZalpha gene (which is located at the 3’ side of the cleavage). To the C-terminus of the lacZalpha gene a lethal ccdB gene is connected. If the ligation is succesful it interrupts the transcription from the lethal gene, thus promotes E. coli growth. To sort the bacterias which do not have the plasmid, there is a Kanamycin resistance gene in the vector. If we spread the bacteria on Kanamycin containing LB only the bacteria that has the insert containing ligated plasmid will outgrow.
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 +
(Kép a vectorról)
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We used gel electrophoresis to check if the bacteria had the right plasmid inside them. Before running, we digested the purified plasmids with NotI restriction enzyme. This digestion leaves us with inserts and vectors separately, because the insert had NotI containing prefix and suffix at the ends. We run them on 110 V for 30 minutes. We used lambda DNA digested with EcorHI and HindIII marker as a ladder.
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 +
(Kép az electroforézisről)
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On the above picture we can see the result of the running. We can see the vector at the fourth line, because its length is 3519 bp. Between the sixth and seventh line we can wee out inserts, their length is 1741 bp and 1829 bp (A/B, C/D respectively)
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https://static.igem.org/mediawiki/parts/1/1e/T--SZTA_Szeged_HU--LambdaLadder.png https://static.igem.org/mediawiki/parts/4/45/T--SZTA_Szeged_HU--Elpho4jo4.png
 
https://static.igem.org/mediawiki/parts/1/1e/T--SZTA_Szeged_HU--LambdaLadder.png https://static.igem.org/mediawiki/parts/4/45/T--SZTA_Szeged_HU--Elpho4jo4.png

Revision as of 17:20, 21 October 2019


McyA/D biderectional promoter 2

This part is constructed to certify the bidirectional transcription from McyD promoter. Normally microcystin toxin-forming protein genes (McyABC and McyDEFGHIJ) are located next to the McyD promoter in both 5’-3 and 3’-5’ directions. When microcystin toxin is present, it enhances the synthesis of these proteins, thus promotes more toxin production. This phenomenon is called autoinduction.

We replaced the toxin-producing genes with a composite GFP, which consists of two parts. We put one part in the 3' direction and the other one in the 5' direction from the McyD promoter. When the two parts are synthesized at the same time they connect together to form an active GFP that glows. Thus The transformed bacteria that has the insert can only glow under UV light if the bidirectional transcription works. This construct consists of the McyD promoter, an RBS, GFP2 and a terminator sequence in the 3' direction from the promoter and a reverse RBS, a reverse GFP1 and a reverse terminator sequence in the 5' direction from the promoter.

(kép a konstruktról)

For cloning we used the Zero Blunt TOPO PCR Cloning Kit from Thermo Fischer Scientific (https://www.thermofisher.com/order/catalog/product/450245?tsid=Email_POE_OC_OrderConfirm%20%0D%20_SKULINK#/450245?tsid=Email_POE_OC_OrderConfirm%20%0D%20_SKULINK). It uses a vector, called pCR-Blunt II-TOPO. The ligation of the vector and insert is done by topoisomerase enzymes, which are connected to the ends of the linearised vector. At the 5’ side of the cleavage there is a Plac promoter, which starts transcription from lacZalpha gene (which is located at the 3’ side of the cleavage). To the C-terminus of the lacZalpha gene a lethal ccdB gene is connected. If the ligation is succesful it interrupts the transcription from the lethal gene, thus promotes E. coli growth. To sort the bacterias which do not have the plasmid, there is a Kanamycin resistance gene in the vector. If we spread the bacteria on Kanamycin containing LB only the bacteria that has the insert containing ligated plasmid will outgrow.

(Kép a vectorról)

We used gel electrophoresis to check if the bacteria had the right plasmid inside them. Before running, we digested the purified plasmids with NotI restriction enzyme. This digestion leaves us with inserts and vectors separately, because the insert had NotI containing prefix and suffix at the ends. We run them on 110 V for 30 minutes. We used lambda DNA digested with EcorHI and HindIII marker as a ladder.

(Kép az electroforézisről)

On the above picture we can see the result of the running. We can see the vector at the fourth line, because its length is 3519 bp. Between the sixth and seventh line we can wee out inserts, their length is 1741 bp and 1829 bp (A/B, C/D respectively)


T--SZTA_Szeged_HU--LambdaLadder.png T--SZTA_Szeged_HU--Elpho4jo4.png


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 1108
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI.rc site found at 1622