Difference between revisions of "Part:BBa K2282013"
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We decided to sequence the biobrick BBa_K2282013 by GATC in order to testified the presence of the whole integrity of the sequence. | We decided to sequence the biobrick BBa_K2282013 by GATC in order to testified the presence of the whole integrity of the sequence. | ||
The results were successful, the part BBa_K2282013 was well sequenced. | The results were successful, the part BBa_K2282013 was well sequenced. | ||
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BBa_K2282013: | BBa_K2282013: | ||
Forward: | Forward: |
Revision as of 12:35, 31 October 2017
mRFP under heat inducible system pL/cI857
Contents
Usage and Biology
This part codes for the full sequence of mRFP, a red fluorescent protein, above 37°C. The construct is composed of a cI857 coding gene behind the strong constitutive promoter J23100 and RBS and an mRFP behind a pL promoter that is regulated by the gene cI857 and RBS. Both cI857 and mRFP coding genes are in front of a terminator. Leftward promoter (pL) derived from phage ƛ is fully repressed at low temperature by the thermolabile cI857 protein. cI857 loses repression activity on the pL promoter when the temperature rise above 30°C until 42°C, when it can no longer bind to pL. The aim of this construct is to code for mRFP when the temperature rises above 30°C, while the transcription is repressed under 30°C.
Source of this part
BBa_K2282013 part has been assembled to the pL promoter - RBS - Double terminator (E.coli his operon terminator). This double terminator was extracted from the strain E.coli K12 MG1655 complete genome, size length 4,641,652 pb in order to be different from the one in the part BBa_K22820012 and avoid concatemers problems.
Design consideration
This part sums up our final heat sensitive construction. The overall strategy we chose is complex and we were not sure it would work. Our bibliographic review and analysis of the Paris-Saclay iGEM 2017 project (using DNA thermometers) we decided to use strong promoters (Anderson BBa_J23100 with its respective RBS and pL promoter) to obtain higher expression levels. We had a slight problem in sequence design with IDT because their system detected our double use of double terminators as concatemers and did not let us introduce the same double terminator BBa_B0015 so we change the double terminator of the new part by an E.coli terminator operon.
References
Norma A Valdez-Cruz, Luis Caspeta, Néstor O Pérez, Octavio T Ramírez, Mauricio A Trujillo-Roldán - Production of recombinant proteins in E.Coli by the heat inducible expression system based on the phage lambda pL and/or pR promoters - Microbial Cell Factories 2010, 9:18.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12INCOMPATIBLE WITH RFC[12]Illegal NheI site found at 7
Illegal NheI site found at 30 - 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25INCOMPATIBLE WITH RFC[25]Illegal AgeI site found at 1745
Illegal AgeI site found at 1857 - 1000COMPATIBLE WITH RFC[1000]
Characterization IONIS_PARIS 2017
Group & Author: IONIS_PARIS /La Paillasse/2017
Summary: We wanted to study if our part worked at a specific temperature above 30 degrees.
Method: We first characterize our part by doing a bacteria culture (BBa_K2282013 - pSB1C3) at 37ºC. We took the DO until it reached 0,5. After that we split it into two falcons, one was stocked at 15ºC and the second one was stoked at 37ºC. After 20h00 of incubation the results were not successful, both colonies were red at 15ºC and 37ºC.
We supposed that when the system heat is activated (red color due to the mRFP), it can not represses the action of the mRFP even if the system is in cold shock temperatures. The problem is that we can not see very well if our part works on high temperatures or not. For the characterization we have always used the part BBa_K2282012 as a control.
We try do change the characterization by making our bacterial transformation with the part BBa_K2282013 growth at room temperature (around 20ºC), normally we should have white colonies in other to start again the characterization and do not perturb the first results.
Figure 1: BBa_K2282013 grown at 25ºC (room temperature).
We decided to sequence the biobrick BBa_K2282013 by GATC in order to testified the presence of the whole integrity of the sequence. The results were successful, the part BBa_K2282013 was well sequenced.
BBa_K2282013:
Forward:
CNNGCGCG TTGGCCG ATTCATT AATGCA GCTGGCAC GACAGGTTTCCCG ACTGGAAAGCGGGC AGTGAGCGCAACGCAA TTAATGTGA GTTAGCTCACTCAT TAGGCACCCCAGG CTTTACACTTTATGC TTCCGGCTCGTAT GTTGTGTGGAATTG TGAGCGGATAACAA TTTCACACATACTA GAGAAAGAGGAGAA ATACTAGATGGC TTCCTCCGAAGAC GTTATCAAAGAGTT CATGCGTTTCAAA GTTCGT ATGGAAGGTTC CGTTAACGGTC ACGAGTTCGAAA TCGAAGGTGA AGGTGAAGGTCGTC CGTACGAAGGTA CCCAGACCGCTA AACTGAAAGTT ACCAAAGGTGGT CCGCTGCCGTTC GCTTGGGACATCC TGTCCCCGCAGTT CCAGTACGGTTCCA AAGCTTACGTTAAA CACCCGGCTGAC ATCCCGGACTACC TGAAACTGTCCTT CCCGGAAGGTTTC AAATGGGAACGTG TTATGAACTTCGAA GACGGTGGTGTTG TTACCGTTACCCAGG ACTCCTCCCTG CAAGACGGTGAG TTCATCTACAAAGTT AAACTGCG TGGTACCAACT TCCCGTCCGAC GGTCCGGTTA TGCAGAAAAA AACCATGGGTTG GGAAGCTT CCACCGAACGTAT GTACCCGGA AGACGGTGC TCTGAAA GGTGAAATCAA AATGCGTCT GAANCTGAA AGACGGTGGTCA CTACGACGCTGA AGTTAAAACCA CCTACATGGCTA AAAANCCG GTTCAGC TGCCG GGTGCTTACA AAACCGACATCAAA CTGGACATCACCTC CCACAACGAAGACTA CACCATCGTTG AACAGTACGAAC GTGCTGAAGGTCGT CACTCCACCGGTGC TTAATAACGCTGATA GTGCTAGTGTAGATC GCTACTAGAGCCAGG CATCAANTAAAACGAA AGGCTCAGTCGAA AGACTGGGCCTT TCGTTTTAT CTGTTGTTTGTCG GTGAACGCTC TCTACTANAGT CNNNCGGGCTC ACCTTCGG NGGGNCCTT TCTGCG
Reverse:
CCNG AGGTGAGCC AGTGTGACT CTAGTAGAGAG CGTTCACC GACAAACAA CAGATAAAACG AAAGGCCCAGT CTTTCGACT GAGCCTTTCG TTTTATTTGA TGCCTGGCTC TAGTAGCGATC TACACTAGCA CTATCAGCG TTATTAAGCA CCGGTGGAGT GACGACCTTCA GCACGTTCGT ACTG TTCAA CGATG GTGTAGTCTT CGTTGTGGGAGG TGATGTCCAGTTT GATGTCGGTTTTG TAAGCACCCGGCA GCTGAACCGGTTT TTTAGCCAT GTAGGTGGTTT TAACTTCAGCGTC GTAGTGACCACC GTCTTTCAGTTTC AGACGCAT TTTGATTTCAC CTTTCAGAGCA CCGTCTT CCGGGTACAT ACGTTCGGT GGAAGCTTCCC AACCCATGGT TTTTTTCTGCAT AACCGGACCGT CGGACGGGAAGTT GGTACCACGCAG TTTAACTTTGT AGATGAACTC ACCGTCTTG CAGGGAGGAG TCCTGGGTA ACGGTAACAA CACCACCGT CTTCGAAGT TCATAACACGT TCCCATTTGA AACCTTCC GGGAAGGACA GTTTCAGGT AGTCCGGG ATGTCAGC CGGGTGTT TAACGTAAG CTTTGGAACCG TACTGGAACTG CGGGGACAG GATGTCCC AAGCGAA CGGCAGCGG ACCACCTTTG GTAACTTTC AGTTTAGCG GTCTGGG TACCTTCG TACGGACGAC CTTCACCTTC ACCTTCGAT TTCGAACTC GTGACC GTTAACGGAA CCTTCCATAC GAACTTTGAA ACGCATGAACT CTTTGATA ACGTC TTCGGAGGA AGCCAT CTAGTATTTCT CCTCTTTCTCT AGTATGTGTGAA NTTGTTATC CGCTCACAATT CCACACAACATA CGAGCCGG AAGCATAANGT GTAAANCCNG GGGGTGCCTA ATGGAGNGAG CTAACNTCACATT NAATTGGCGTTG NNGCTCACT GGCCCGCT TTTCCAGT CCGGAA
IMPROVEMENT REFERENCE: IONIS_PARIS 2017
However, as we saw that our biobrick doesn't work, we thought about a possible reconversion for this part. Indeed, this part contains the valuable part BBa_K098997 corresponding to the cI lambda repressor. Even though, the part BBa_K2282013 could be used as a reporter gene to show visually the successful transformation of the cI lambda repressor gene in E.coli. That way, when an iGEM team wishes to characterize the part BBa_K098997 they can use our part and will not need to do PCR colony to select the right transformed colony. However, the part BBa_K2282013 does not report the expression of the cI lambda repressor gene, but only its presence.
The part improved is: BBa_K098997 (Group: iGEM08_Harvard), Designed by: Harvard iGEM 08.