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<u><p class="title1" id="select1">pSB<sub>BS</sub>0K-Mini: new part <a href="http://parts.igem.org/Part:BBa_K1937001">BBa_K1937001</a></p></u> | <u><p class="title1" id="select1">pSB<sub>BS</sub>0K-Mini: new part <a href="http://parts.igem.org/Part:BBa_K1937001">BBa_K1937001</a></p></u> | ||
<p class="texteb"> | <p class="texteb"> | ||
− | We reasoned that most of the pSB<sub>BS</sub>0K-P plasmid content were of no need to our project ( | + | We reasoned that most of the pSB<sub>BS</sub>0K-P plasmid content were of no need to our project (<i>lacY, rfp, |
− | + | lacI</i>…). Since supressing these elements also suppressed the suffix and prefix, primers with new suffix | |
and prefix were designed to amplify the needed regions (selection markers and replication origins; | and prefix were designed to amplify the needed regions (selection markers and replication origins; | ||
− | figure 1). Nhe1 restriction site was also added at the 5’ end of each primers to circularize the PCR | + | figure 1). <i>Nhe1</i> restriction site was also added at the 5’ end of each primers to circularize the PCR |
product. | product. | ||
<!-- ###### FIGURE ##### --> | <!-- ###### FIGURE ##### --> | ||
− | <center><img src="https://static.igem.org/mediawiki/2016/e/e7/Toulouse_France_backbone1.jpg" style="width: | + | <center><img src="https://static.igem.org/mediawiki/2016/e/e7/Toulouse_France_backbone1.jpg" style="width:60%; margin:20px 20px;"></center> |
<b style="font-size:12px;"> | <b style="font-size:12px;"> | ||
Figure 1: reduction of the pSB<sub>BS</sub>0K-P plasmid. Position of the primers are indicated by the blue arrow on pSB<sub>BS</sub>0K-P (left part of the figure). The resulting PCR fragment is the blue pointed line. After digestion by NheI and self-ligation, the resulting pSB<sub>BS</sub>0K-Mini plasmid was obtained (right part of the figure). | Figure 1: reduction of the pSB<sub>BS</sub>0K-P plasmid. Position of the primers are indicated by the blue arrow on pSB<sub>BS</sub>0K-P (left part of the figure). The resulting PCR fragment is the blue pointed line. After digestion by NheI and self-ligation, the resulting pSB<sub>BS</sub>0K-Mini plasmid was obtained (right part of the figure). | ||
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With the success of the pSB<sub>BS</sub>0K-Mini, we decided that we should try to go even further by isolating | With the success of the pSB<sub>BS</sub>0K-Mini, we decided that we should try to go even further by isolating | ||
− | what is the very essence of this replicative <i>Bacillus</i> plasmid: its <i>Bacillus</i> | + | what is the very essence of this replicative <i>Bacillus</i> plasmid: its <i>Bacillus repU</i> origin and its kanamycin |
resistance gene. We amplified the region containing these two elements with primers carrying the | resistance gene. We amplified the region containing these two elements with primers carrying the | ||
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<!-- ###### FIGURE ##### --> | <!-- ###### FIGURE ##### --> | ||
− | <center><img src="https://static.igem.org/mediawiki/2016/c/ca/Toulouse_France_backbone2.jpg" style="width: | + | <center><img src="https://static.igem.org/mediawiki/2016/c/ca/Toulouse_France_backbone2.jpg" style="width:60%; margin:20px 20px;"></center> |
<b style="font-size:12px;"> | <b style="font-size:12px;"> | ||
− | Figure 2: creation of the OriKan cassette. Position of the primers are indicated by the blue arrow on pSB<sub>BS</sub>0K-P (left part of the figure). The resulting PCR fragment is the blue pointed line. After digestion by EcoRI and PstI and ligation in the pSB1C3 plasmid, the resulting pSB1C3-OriKan plasmid was obtained (right part of the figure). | + | Figure 2: creation of the OriKan cassette. Position of the primers are indicated by the blue arrow on pSB<sub>BS</sub>0K-P (left part of the figure). The resulting PCR fragment is the blue pointed line. After digestion by <i>EcoRI</i> and <i>PstI</i> and ligation in the pSB1C3 plasmid, the resulting pSB1C3-OriKan plasmid was obtained (right part of the figure). |
</b> | </b> | ||
<br><br> | <br><br> | ||
− | The fragment was then sub-cloned in the pSB1C3 plasmid (between the EcoRI/PstI restriction sites). | + | The fragment was then sub-cloned in the pSB1C3 plasmid (between the <i>EcoRI/PstI</i> restriction sites). |
We checked the capacity of this new pSB1C3-Orikan plasmid to maintain in <i>Bacillus subtilis</i> and we | We checked the capacity of this new pSB1C3-Orikan plasmid to maintain in <i>Bacillus subtilis</i> and we |
Latest revision as of 23:13, 19 October 2016
Backbones description
Backbone
The use of replicative plasmid in Bacillus subtilis is not as usual as in E. coli.
Only one of such plasmid is described in the iGEM registry (pSBBS0K-P from iGEM Munich 2012;
BBa_K823026 and its slightly modified form BBa_K1351040).
Since none of them were available from the registry, we eventually got BBa_K1351040 from ex-Munich iGEMers (thanks guys!).
However, this plasmid is already huge (9358 bp), and we needed to insert great fragments inside.
Our first attempts to clone in BBa_K1351040 failed. We therefore decided to operate a reduction of the plasmid size.
pSBBS0K-Mini: new part BBa_K1937001
We reasoned that most of the pSBBS0K-P plasmid content were of no need to our project (lacY, rfp, lacI…). Since supressing these elements also suppressed the suffix and prefix, primers with new suffix and prefix were designed to amplify the needed regions (selection markers and replication origins; figure 1). Nhe1 restriction site was also added at the 5’ end of each primers to circularize the PCR product.
The new plasmid size is smaller by 3604 bp. It was purified from E. coli and used to successfully transform B. subtilis. Integrity of the whole sequence was assessed by sequencing using 10 primers distributed all along the sequence. This new plasmid was then used to create most of the Bacillus subtilis parts of our project, demonstrating its efficiency as a new backbone for Bacillus based projects.
OriKan (new part BBa_K1937002): and they all became Bacillus plasmids…
With the success of the pSBBS0K-Mini, we decided that we should try to go even further by isolating what is the very essence of this replicative Bacillus plasmid: its Bacillus repU origin and its kanamycin resistance gene. We amplified the region containing these two elements with primers carrying the iGEM suffix and prefix (figure 2).
The fragment was then sub-cloned in the pSB1C3 plasmid (between the EcoRI/PstI restriction sites). We checked the capacity of this new pSB1C3-Orikan plasmid to maintain in Bacillus subtilis and we were delighted to obtain clones. The actual presence of pSB1C3-Orikan in this colonies was assessed by PCR (figure 3). The sequence integrity of the OriKan cassette was also verified.
These results demonstrate that the OriKan biobrick is sufficient to turn any pSB1C3 plasmid into a Bacillus subtilis compatible replicative plasmid.
Conclusions and perspectives
The start of our project has been complicated by the absence of available replicative plasmid for
Bacillus subtilis in the registry. Even managing to obtained one was not the end of our quest since it
appears to be too big for further sub-cloning purposes. In this context, obtaining the pSBBS0K-Mini
has been a great step forward for us as it allowed a fast progression of our project cloning steps.
Moreover, we are also very proud of the OriKan biobrick. There was no such part in the registry. Its
capacity to simply functionalize any registry part for Bacillus subtilis (and likely some other gram
positive strains) is invaluable for the ever growing numbers of iGEM projects based on these
organisms. We therefore applied for the OriKan biobrick to be selected as “best composite part”.
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