Difference between revisions of "Part:BBa K1949000"

 
(58 intermediate revisions by 8 users not shown)
Line 1: Line 1:
_NOTOC__
+
__NOTOC__
 
<partinfo>BBa_K1949000 short</partinfo>
 
<partinfo>BBa_K1949000 short</partinfo>
  
This new promoter, a cold inducible promoter (we call this Pcold) consists of the cspA promoter, Cold Box, 5’-UTR, RBS and DB. This promoter is used to effectively produce proteins at low temperatures.
+
[[Image:Cold_fig1.png|thumb|center|400px| We characterize cold inducible promoter (Pcold) by this construction. ]]<br>
 +
 
 +
<span style="margin-left: 10px;">This promoter is used to effectively produce proteins at low temperatures. This new promoter, a cold inducible promoter (we call this Pcold) consists of the <i>cspA</i> promoter, Cold Box, 5’-UTR, RBS and DB. The combination (of <i>cspA</i> promoter which is active at both low and high temperature, Cold box which inhibits excessive gene expression, 5’UTR which is stable at only low temperature, and DB which function as an extra RBS) activates gene expression at low temperatures.
 +
 
 +
 
 +
===Characterization===
 +
<span style="margin-left: 10px;">RFU (Relative Fluorescence Units) of GFP / Turbidity was measured using cells cultured at 18℃ and 37℃ to confirm function of Pcold. The cells harbored a plasmid which carries Pcold-<i>gfp</i> or Ptet-<i>rbs-gfp</i>.
 +
 
 +
 
 +
[[Image:cold3.png|thumb|center|400px|Fig.1  RFU of <i>E. coli</i> which harbored Pcold<i>-gfp</i> at 18℃ was about twice higher than that at 37℃.]]<br>
 +
 
 +
[[Image:cold2.png|thumb|center|400px| Fig.2 RFU of <i>E. coli</i> which harbored Ptet<i>-rbs-gfp</i> at 18℃ was about eight fold higher than that at 37℃. ]]<br>
 +
 
 +
 
 +
<span style="margin-left: 10px;"><i>E. coli</i> cells which carry the Ptet-<i>rbs-gfp</i> plasmid was cultured at 18℃, and RFU of GFP was measured at indicated time points. (Fig.1) Also, the same experiment was performed at 37℃. We thought this result was obtained because GFP is easily folded into correct structures at low temperatures. By contrast, RFU of <i>E. coli</i> which harbored Pcold<i>-gfp</i> at 18℃ was about eight fold higher than that at 37℃. From this result, we confirmed Pcold activates gene expression at low temperatures.(Fig.2)
 +
 
 +
 
 +
 
 +
===Biobrick Tips===
 +
<span style="margin-left: 10px;">This part is not able to be used for most common assembly, because restriction enzyme digestion with <i>Xba</i>I and <i>Spe</i>I generates an unexpected stop codon. Therefore, this part do not meet the criteria of basic parts construction. Our team generated a unique digestion site, <i>Bam</i>HI at the upstream of the suffix. We recommend to use this <i>Bam</i>HI site for cloning.
 +
 
 +
 
 +
===Reference===
 +
Famg L,Hou Y and Inoue M.1998. Role of <i>Escherichia coli</i> <i>cspA</i> promoter sequences and adaptation of translational apparatus in the cold shock response. Mol Gen Genet. 1997 Oct;256(3):282-90
 +
 
 +
Goldenberg D,Azar I,Oppenheim AB,Brandi A,Pon CL,Gualerzi CO. Role of the cold-box region in the 5' untranslated region of the <i>cspA</i> mRNA in its transient expression at low temperature in <i>Escherichia coli</i>. J Bacteriol. 1998 Jan;180(1):90-5.
 +
 
 +
Nakashima N and Tamura T. 2004. Cell-free protein synthesis using cell extract of <i>Pseudomonas fluorescens</i> and <i>CspA</i> promoter. Biochemical and Biophysical Research Communications 319 (2004) 672
 +
 
 +
Yamanaka K.1999. Cold Shock Response in Escherichia coli. J. Mol. Microbiol. Biotechnol. (1999) 1(2): 193-202
 +
 
  
  
Line 17: Line 47:
 
<partinfo>BBa_K1949000 parameters</partinfo>
 
<partinfo>BBa_K1949000 parameters</partinfo>
 
<!-- -->
 
<!-- -->
 +
 +
===Characterization IONIS_PARIS 2017===
 +
 +
Group & Authors: (IONIS_PARIS/La Paillasse, 2017)
 +
 +
 +
Summary: We chose to ameliorate BBa_K1949000 current characterization by measuring the GFP expression level at additional temperatures compared to the existing data obtained by the team (18°C and 37°C). We made this choice because of the similarities between the Tokyo 2016 team cold-response system and ours.
 +
 +
For the protocol you can see it in our wiki IONIS_PARIS 2017- Laboratory work - Protocols. 
 +
 +
Methods: Both BBa_I20260 (constitutive GFP) and BBa_K1949000 (pCOLD-GFP) plasmids were transformed into E.Coli bacteria. These were cultured in liquid medium added with chloramphenicol, and incubated at 37°C for 6 hours. We then transferred them at 27°C and measured the resulting fluorescence every hour for 24h.
 +
 +
 +
 +
https://static.igem.org/mediawiki/2017/thumb/0/05/Ionis-paris-2017-HP-characterization-pCOLD.png/800px-Ionis-paris-2017-HP-characterization-pCOLD.png
 +
 +
Figure 1: Fluoresence of GFP/cell from parts BBa K1949000 (pCOLD-GFP) and BBa_I20260 (constitutive GFP) over 24h at both 27°C and 37°C.
 +
 +
Interpretation :
 +
 +
We chose 27°C because it was between 18°C and 37°C and could therefore supplement the current characteristic state of the part. What we can see overall is the non-expression of GFP at both 27 and 37°C under the pCOLD promoter (pCOLD-GFP), which is consistent with the construction of this promoter. Indeed, this promoter relies on a cold-inducible system inspired by the cold-shock protein A (cspA). The pCOLD-GFP system permits the transcription of the GFP gene under the form of a cold-inducible RNA thermometer.
 +
 +
We can see that pCOLD-GFP expression does not vary highly with time and remains very low after 25h of incubation.
 +
We can however notice that there is still a faint expression of pCOLD-GFP at both 27°C and 37°C. We assume it is normal, because from the total pool of pCOLD-GFP mRNA, a little proportion should still be translated. Indeed, it had been reported that the CspA mRNA was stable 15 minutes at 15°C and 12 seconds at 37°C, and that cold-shock proteins were still translated at high temperatures but in very low amount.
 +
 +
Overall this shows that the system works at these temperatures by repressing the GFP expression at both 27 and 37°C.
 +
 +
We decided to sequence the biobrick BBa_K1949000 by GATC in order to testified the presence of the whole integrity of the sequence. The results were successful, the part BBa_K1949000 was well sequenced.
 +
 +
pCold sequenced:
 +
 +
Forward Primer:
 +
 +
TGAGCCNGTGTGACT
 +
CTAGTAGAGAGCGTTCACC
 +
GACAAACAACAGA
 +
TAAAANGAAAGG
 +
CCCAGTCTTTCG
 +
ACTGAGC
 +
CTTTCGTTTT
 +
ATTTGATGCC
 +
TGGCTCTAGT
 +
ATTATTATTTGT
 +
ATAG
 +
TTCATCNNNG
 +
NNATGTGTAATC
 +
CCAGCAGCTGTT
 +
ACAAACTCAAGA
 +
AGGACCATG
 +
TGGTCTCTC
 +
TTTTCGTTG
 +
GGATCTTTCG
 +
AAAGGGCAG
 +
ATTGTGTGG
 +
ACAGGTAATGG
 +
TTGTCTGGT
 +
AAAAGGACAG
 +
GGCCATCGC
 +
CAATTGGAGTA
 +
TTTTGTTGATAA
 +
TGGTCTGCTA
 +
GTTGAACG
 +
CTTCCATCT
 +
TCAATGTTGTG
 +
TCTAATTTTGA
 +
AGTTAA
 +
CTTTGATTCCATTCTTT
 +
TGNTTGTCTGCCA
 +
TGATGTATACATTGT
 +
GTGAGTTATAGTTG
 +
TATTCCAATTTGT
 +
GTCCAAGAATGTT
 +
TCCATCTNCTTTAA
 +
AATCANTACCTTTT
 +
AACTCGATTCTA
 +
TTAACAAGGGT
 +
ATCACCTTCA
 +
AACTTGACTTC
 +
AGCACGTGTCTTG
 +
TANTTCCCGTCA
 +
TCTTTGAAAAA
 +
TATAGNTCTTT
 +
CCTGTACA
 +
TAACCTTCNG
 +
GCATGNCACT
 +
CTTGAAAAA
 +
GTCATGN
 +
TGTTTCATA
 +
TGATCTG
 +
GGTATC
 +
TCGCAAAGC
 +
ATTGAC
 +
ACCATAACCGA
 +
AAGTAG
 +
NNACAAG
 +
TGTTGGN
 +
CCATGGAN
 +
CAGG
 +
 +
https://static.igem.org/mediawiki/2017/thumb/2/2d/Ionis-paris-2017-Characterization_R%26D-_seq_pcold_pref.png/800px-Ionis-paris-2017-Characterization_R%26D-_seq_pcold_pref.png
 +
 +
Figure 1: Sequencing part BBa_K1949000 by GATC (forward primer)
 +
 +
 +
Reverse Primer:
 +
 +
GGACCGTTTT
 +
CCNACCG
 +
ATTAATCATA
 +
AATATGAAAAA
 +
TAATTGTTG
 +
CATCACCCGC
 +
CAATGC
 +
GTGGCTTA
 +
ATGCACAT
 +
CAACGGTTT
 +
GACGTACAG
 +
ACCATTAA
 +
AGCAGTGTAG
 +
TAAGGCAAGTC
 +
CCTTCAAG
 +
AGTTATCGTTG
 +
ATACCCATCGTAG
 +
TGCACATTCCT
 +
TTAACGCTTCA
 +
AAATCTGTAAA
 +
GCACGCCATAT
 +
CGCCGAAAG
 +
GCACAC
 +
TTAATTAT
 +
TAAAGGTAA
 +
TACACTATGT
 +
CCGGTAAAAT
 +
GACTGGTATC
 +
GTAAAATGGT
 +
TCAACGCCG
 +
GATCCATG
 +
CGTAAAG
 +
GAGAAGAA
 +
CTTTTCA
 +
CTGGAGTTG
 +
TCCCAATT
 +
CTTGTTG
 +
AATTAGAT
 +
GGTGATGTT
 +
AATGGGCA
 +
CAAATTTT
 +
CTGTCAG
 +
TGGAGAGG
 +
GTGAAGGTG
 +
ATGCAA
 +
CATAC
 +
GGAAA
 +
ACTTACC
 +
CTTAAATT
 +
TATTTGC
 +
ACTACTGGA
 +
AAACTACCTG
 +
TTCCATGGCCAAC
 +
ACTTGTCACT
 +
ACTTTCGGTT
 +
ATGGTGTT
 +
CAATGCT
 +
TTGCGAGAT
 +
ACCCAGATC
 +
ATATGAAACA
 +
GCATGACT
 +
TTTTCAA
 +
GAGTGC
 +
CATGC
 +
CCGAAGGT
 +
TATGTAC
 +
AGGAAAG
 +
AACTAT
 +
ATTTTTNA
 +
AAGATG
 +
ACGGGAAC
 +
TACNANAC
 +
 +
https://static.igem.org/mediawiki/2017/thumb/a/a9/Ionis-paris-2017-Characterization_R%26D-_seq_pcold_REVERSE.png/800px-Ionis-paris-2017-Characterization_R%26D-_seq_pcold_REVERSE.png
 +
 +
Figure 2: Sequencing part BBa_K1949000 by GATC (reverse primer)
 +
 +
The results from the characterization were successful. We went the part to the registry as it was not available.

Latest revision as of 00:44, 2 November 2017

cold inducible promoter (Pcold)

We characterize cold inducible promoter (Pcold) by this construction.

This promoter is used to effectively produce proteins at low temperatures. This new promoter, a cold inducible promoter (we call this Pcold) consists of the cspA promoter, Cold Box, 5’-UTR, RBS and DB. The combination (of cspA promoter which is active at both low and high temperature, Cold box which inhibits excessive gene expression, 5’UTR which is stable at only low temperature, and DB which function as an extra RBS) activates gene expression at low temperatures.


Characterization

RFU (Relative Fluorescence Units) of GFP / Turbidity was measured using cells cultured at 18℃ and 37℃ to confirm function of Pcold. The cells harbored a plasmid which carries Pcold-gfp or Ptet-rbs-gfp.


Fig.1 RFU of E. coli which harbored Pcold-gfp at 18℃ was about twice higher than that at 37℃.

Fig.2 RFU of E. coli which harbored Ptet-rbs-gfp at 18℃ was about eight fold higher than that at 37℃.


E. coli cells which carry the Ptet-rbs-gfp plasmid was cultured at 18℃, and RFU of GFP was measured at indicated time points. (Fig.1) Also, the same experiment was performed at 37℃. We thought this result was obtained because GFP is easily folded into correct structures at low temperatures. By contrast, RFU of E. coli which harbored Pcold-gfp at 18℃ was about eight fold higher than that at 37℃. From this result, we confirmed Pcold activates gene expression at low temperatures.(Fig.2)


Biobrick Tips

This part is not able to be used for most common assembly, because restriction enzyme digestion with XbaI and SpeI generates an unexpected stop codon. Therefore, this part do not meet the criteria of basic parts construction. Our team generated a unique digestion site, BamHI at the upstream of the suffix. We recommend to use this BamHI site for cloning.


Reference

Famg L,Hou Y and Inoue M.1998. Role of Escherichia coli cspA promoter sequences and adaptation of translational apparatus in the cold shock response. Mol Gen Genet. 1997 Oct;256(3):282-90

Goldenberg D,Azar I,Oppenheim AB,Brandi A,Pon CL,Gualerzi CO. Role of the cold-box region in the 5' untranslated region of the cspA mRNA in its transient expression at low temperature in Escherichia coli. J Bacteriol. 1998 Jan;180(1):90-5.

Nakashima N and Tamura T. 2004. Cell-free protein synthesis using cell extract of Pseudomonas fluorescens and CspA promoter. Biochemical and Biophysical Research Communications 319 (2004) 672

Yamanaka K.1999. Cold Shock Response in Escherichia coli. J. Mol. Microbiol. Biotechnol. (1999) 1(2): 193-202


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BamHI site found at 308
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


Characterization IONIS_PARIS 2017

Group & Authors: (IONIS_PARIS/La Paillasse, 2017)


Summary: We chose to ameliorate BBa_K1949000 current characterization by measuring the GFP expression level at additional temperatures compared to the existing data obtained by the team (18°C and 37°C). We made this choice because of the similarities between the Tokyo 2016 team cold-response system and ours.

For the protocol you can see it in our wiki IONIS_PARIS 2017- Laboratory work - Protocols.

Methods: Both BBa_I20260 (constitutive GFP) and BBa_K1949000 (pCOLD-GFP) plasmids were transformed into E.Coli bacteria. These were cultured in liquid medium added with chloramphenicol, and incubated at 37°C for 6 hours. We then transferred them at 27°C and measured the resulting fluorescence every hour for 24h.


800px-Ionis-paris-2017-HP-characterization-pCOLD.png

Figure 1: Fluoresence of GFP/cell from parts BBa K1949000 (pCOLD-GFP) and BBa_I20260 (constitutive GFP) over 24h at both 27°C and 37°C.

Interpretation :

We chose 27°C because it was between 18°C and 37°C and could therefore supplement the current characteristic state of the part. What we can see overall is the non-expression of GFP at both 27 and 37°C under the pCOLD promoter (pCOLD-GFP), which is consistent with the construction of this promoter. Indeed, this promoter relies on a cold-inducible system inspired by the cold-shock protein A (cspA). The pCOLD-GFP system permits the transcription of the GFP gene under the form of a cold-inducible RNA thermometer.

We can see that pCOLD-GFP expression does not vary highly with time and remains very low after 25h of incubation. We can however notice that there is still a faint expression of pCOLD-GFP at both 27°C and 37°C. We assume it is normal, because from the total pool of pCOLD-GFP mRNA, a little proportion should still be translated. Indeed, it had been reported that the CspA mRNA was stable 15 minutes at 15°C and 12 seconds at 37°C, and that cold-shock proteins were still translated at high temperatures but in very low amount.

Overall this shows that the system works at these temperatures by repressing the GFP expression at both 27 and 37°C.

We decided to sequence the biobrick BBa_K1949000 by GATC in order to testified the presence of the whole integrity of the sequence. The results were successful, the part BBa_K1949000 was well sequenced.

pCold sequenced:

Forward Primer:

TGAGCCNGTGTGACT CTAGTAGAGAGCGTTCACC GACAAACAACAGA TAAAANGAAAGG CCCAGTCTTTCG ACTGAGC CTTTCGTTTT ATTTGATGCC TGGCTCTAGT ATTATTATTTGT ATAG TTCATCNNNG NNATGTGTAATC CCAGCAGCTGTT ACAAACTCAAGA AGGACCATG TGGTCTCTC TTTTCGTTG GGATCTTTCG AAAGGGCAG ATTGTGTGG ACAGGTAATGG TTGTCTGGT AAAAGGACAG GGCCATCGC CAATTGGAGTA TTTTGTTGATAA TGGTCTGCTA GTTGAACG CTTCCATCT TCAATGTTGTG TCTAATTTTGA AGTTAA CTTTGATTCCATTCTTT TGNTTGTCTGCCA TGATGTATACATTGT GTGAGTTATAGTTG TATTCCAATTTGT GTCCAAGAATGTT TCCATCTNCTTTAA AATCANTACCTTTT AACTCGATTCTA TTAACAAGGGT ATCACCTTCA AACTTGACTTC AGCACGTGTCTTG TANTTCCCGTCA TCTTTGAAAAA TATAGNTCTTT CCTGTACA TAACCTTCNG GCATGNCACT CTTGAAAAA GTCATGN TGTTTCATA TGATCTG GGTATC TCGCAAAGC ATTGAC ACCATAACCGA AAGTAG NNACAAG TGTTGGN CCATGGAN CAGG

800px-Ionis-paris-2017-Characterization_R%26D-_seq_pcold_pref.png

Figure 1: Sequencing part BBa_K1949000 by GATC (forward primer)


Reverse Primer:

GGACCGTTTT CCNACCG ATTAATCATA AATATGAAAAA TAATTGTTG CATCACCCGC CAATGC GTGGCTTA ATGCACAT CAACGGTTT GACGTACAG ACCATTAA AGCAGTGTAG TAAGGCAAGTC CCTTCAAG AGTTATCGTTG ATACCCATCGTAG TGCACATTCCT TTAACGCTTCA AAATCTGTAAA GCACGCCATAT CGCCGAAAG GCACAC TTAATTAT TAAAGGTAA TACACTATGT CCGGTAAAAT GACTGGTATC GTAAAATGGT TCAACGCCG GATCCATG CGTAAAG GAGAAGAA CTTTTCA CTGGAGTTG TCCCAATT CTTGTTG AATTAGAT GGTGATGTT AATGGGCA CAAATTTT CTGTCAG TGGAGAGG GTGAAGGTG ATGCAA CATAC GGAAA ACTTACC CTTAAATT TATTTGC ACTACTGGA AAACTACCTG TTCCATGGCCAAC ACTTGTCACT ACTTTCGGTT ATGGTGTT CAATGCT TTGCGAGAT ACCCAGATC ATATGAAACA GCATGACT TTTTCAA GAGTGC CATGC CCGAAGGT TATGTAC AGGAAAG AACTAT ATTTTTNA AAGATG ACGGGAAC TACNANAC

800px-Ionis-paris-2017-Characterization_R%26D-_seq_pcold_REVERSE.png

Figure 2: Sequencing part BBa_K1949000 by GATC (reverse primer)

The results from the characterization were successful. We went the part to the registry as it was not available.